Multi-access Switchgear Assembly

ABSTRACT

A metal clad switchgear assembly comprising multiple compartments defined within an electrical enclosure is provided. The compartments interchangeably accommodate electrical components, for example, current transformers, a circuit breaker, a control power transformer, an epoxy encapsulated potential transformer, etc., electrical cables, and bus bars in predetermined positions for allowing front access and/or rear access to them. One or more compartments are configured for enabling the electrical cables to enter into and/or exit out from the electrical enclosure for allowing front and/or rear access to the electrical cables. A mounting block assembly is positioned in one or more of the compartments for mounting, enclosing, and providing front access to the electrical components. One or more infrared windows and inspection windows are positioned on a front side and/or a rear side of the switchgear assembly for scanning and providing a visual indication of the electrical components, the electrical cables, and the bus bars.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part application of non-provisional patent application Ser. No. 12/905,077 titled “Front Accessible Switchgear Assembly”, filed on Oct. 14, 2010 in the United States Patent and Trademark Office, and claims the benefit of provisional patent application No. 61/352,022 titled “Multi-access Switchgear Assembly”, filed on Jun. 7, 2010 in the United States Patent and Trademark Office.

The specifications of the above referenced patent applications are incorporated herein by reference in their entirety.

BACKGROUND

The apparatus disclosed herein, in general, relates to electrical enclosures. More particularly, the apparatus disclosed herein relates to electrical enclosures that provide, for example, front access only, and front and rear access herein referred to a “multi-access”, to electrical bus members, multiple electrical components, and apparatuses housed within the electrical enclosures. Furthermore, the apparatus disclosed herein relates to electrical bus assemblies for electrical enclosures and arc resistant electrical enclosures.

Medium voltage electrical components and apparatuses, for example, circuit breakers, potential transformers, current transformers, control power transformers, etc., are often housed in an electrical enclosure called a switchgear cabinet. The medium voltage electrical components and apparatuses operate, for example, in a range of about 1000 volts to about 100,000 volts. The switchgear cabinet for medium voltage equipment typically occupies a large space and is difficult to access. As such, maintenance and space considerations are driving factors in the design of new electrical equipment. There is a need for constructing a switchgear assembly that makes efficient use of the available floor space and minimizes the time required for inspection, repair and maintenance of equipment accommodated within the switchgear assembly.

Switchgear cabinets, particularly medium voltage metal clad switchgear cabinets are often damaged due to arcing. An explosion caused by arcing within a switchgear cabinet results in significant economic loss due to interruption of energy distribution, and damage of the switchgear cabinet and the electrical components or equipment accommodated in the switchgear cabinet. Consequently, maintenance personnel inspecting and servicing the switchgear cabinets have to wear protective gear that is bulky and expensive. Typical arc resistant switchgear cabinets tend to be very large and often have heavy sheet metal enclosures. Such configurations require significant space. Some switchgear cabinets employ an external arcing chamber that limits the configuration of the electrical components, equipment, etc., within the switchgear cabinet.

Conventional switchgear cabinets typically provide only a single access, that is, a front access or a rear access to the electrical components and electrical cables within the switchgear cabinet, which places restrictions on the arrangement of the electrical components and the electrical cables within the switchgear cabinet. Therefore, single access switchgear cabinets do not make an efficient use of the available floor space owing to the lesser flexibility available in positioning the electrical components and the electrical cables within the switchgear cabinet. Moreover, conventional single access switchgear cabinets do not allow accommodation of multiple electrical components along with electrical cables in a single section. Hence, there is a need for a switchgear cabinet that provides both front access and rear access to the electrical components and the electrical cables for providing increased flexibility in positioning of the electrical components and the electrical cables within the switchgear cabinet, which results in efficient use of space and flexible accessibility. Moreover, there is a need for a switchgear cabinet that enables accommodation of multiple electrical components in a single section of the switchgear cabinet, thereby minimizing requirement of additional sections.

Furthermore, conventional switchgear cabinets utilize bar type current transformers that are mounted in the rear making it difficult to replace a transformer in the field if one of the transformers fail. Therefore, there is a need for mounting transformers and other electrical components in the front of the switchgear cabinet for easier accessibility for maintenance and inspection.

Moreover, there are significant limitations with respect to the size of potential transformers and control power transformers that are available in conventional switchgear cabinets. For example, the maximum voltage for a potential transformer in a conventional metal clad switchgear cabinet is about 5000V and the maximum power for a control power transformer is about 5 kVA.

Conventional metal clad switchgear cabinets for the North American market need to meet stringent Institute of Electrical and Electronics Engineers (IEEE) requirements and American National Standards Institute (ANSI) requirements. These standards require a circuit breaker to be tested inside the switchgear cabinets that have limited cooling and therefore limiting the temperature rise within the switchgear cabinet becomes a major challenge. Furthermore, as per International Electrotechnical Commission (IEC) standards, barriers between compartments in the switchgear cabinets are not a requirement, therefore cooling the circuit breaker within the switchgear cabinet is much easier. IEC designed equipment, would have to be derated significantly if no changes are made.

Furthermore, conventional metal clad switchgear cabinets pose additional challenges to meet ANSI and Underwriters Laboratories (UL) requirements because of limited space and limited cooling. In addition, IEEE/ANSI designed equipment requires bus bars within the switchgear cabinet to be insulated, making it more difficult to cool the critical current carrying bus bars in certain compartments of the switchgear cabinet that accommodate the circuit breaker. Alternatively, expensive heat sinks have to be employed to limit temperature rise. The addition of heat sinks is a difficult task in the compact space available and poses significant challenges to pass the required lightning impulse test due to space limitations and the shape of the heat sink.

Hence, there is a long felt but unresolved need for an arc resistant metal clad switchgear assembly that has a compact footprint and provides either front access only, or front access and rear access herein referred to as “multi-access” to electrical components, electrical cables, and equipment accommodated in the switchgear assembly for inspection, testing and maintenance with limited space requirements and without protective gear. Moreover, there is a need for a compact switchgear assembly that allows increased flexibility in positioning of the electrical components and the electrical cables within the switchgear assembly without limitations in configurations of the electrical components, and that also enables accommodation of multiple electrical components along with the electrical cables in a single section of the switchgear assembly. Furthermore, there is a need for a compact switchgear assembly that allows successful testing of the electrical components, for example, circuit breakers that are accommodated in the switchgear assembly without additional heat sinks.

SUMMARY OF THE INVENTION

This summary is provided to introduce a selection of concepts in a simplified form that are further described in the detailed description of the invention. This summary is not intended to identify key or essential inventive concepts of the claimed subject matter, nor is it intended for determining the scope of the claimed subject matter.

The metal clad switchgear assembly disclosed herein addresses the above stated need for a compact arc resistant metal clad switchgear assembly that has a compact footprint and provides either front access only, or front access and rear access herein referred to as “multi-access” to electrical components, electrical cables, and equipment accommodated in the switchgear assembly for inspection, testing and maintenance with limited space requirements and without protective gear. The metal clad switchgear assembly disclosed herein allows increased flexibility in positioning of the electrical components and the electrical cables within the metal clad switchgear assembly without limitations in configurations of the electrical components, and also enables accommodation of multiple electrical components along with the electrical cables in a single section of the metal clad switchgear assembly. Adjacent sections defined in an electrical enclosure of the metal clad switchgear assembly are separated by vertical metal barriers for compartmentalizing active electrical components in the electrical enclosure. The “metal clad switchgear assembly” is herein referred to as a “switchgear assembly”.

The switchgear assembly disclosed herein allows access to the electrical components, the electrical cables, equipment, etc., accommodated within the switchgear assembly from the front side only, or from the front side and the rear side of the switchgear assembly. The switchgear assembly that allows access to the electrical components, the electrical cables, the equipment, etc., accommodated within the switchgear assembly from the front side only is herein referred to as a “front accessible switchgear assembly”. The switchgear assembly that allows access to the electrical components, the electrical cables, the equipment, etc., accommodated within the switchgear assembly from the front side and/or the rear side of the switchgear assembly is herein referred to as a “multi-access switchgear assembly”. The switchgear assembly disclosed herein allows successful testing of the electrical components, for example, circuit breakers, that are accommodated in the switchgear assembly without additional heat sinks.

The switchgear assembly disclosed herein comprises multiple compartments defined within an electrical enclosure, a mounting block assembly, multiple electrical components, electrical cables, and bus bars. The electrical enclosure is divided into, for example, a first section and a second section. The compartments comprising, for example, upper compartments, middle compartments, lower compartments, a central compartment, rear compartments, etc., are defined in the first section and the second section of the electrical enclosure. The compartments are configured to interchangeably accommodate one or more electrical components, electrical cables, and bus bars. The electrical cables comprise, for example, input electrical cables and output electrical cables. One or more of the compartments, for example, an upper compartment, a front lower component, and/or a rear lower compartment are configured for enabling the electrical cables to enter into and/or exit out from the electrical enclosure for allowing front access and/or rear access to the electrical cables. The electrical components and the electrical cables are electrically connected in predetermined positions in the compartments for allowing front access and/or rear access to the electrical components, the electrical cables, and the bus bars within the electrical enclosure. One or more of the electrical components and the electrical cables are in electrical communication with one or more of the bus bars in one or more of the compartments. In an embodiment, a low voltage compartment is configured, for example, in one of the upper compartments, the middle compartments, and/or the lower compartments, and isolated from the other compartments.

The switchgear assembly disclosed herein further comprises a plenum chamber rearwardly positioned in the electrical enclosure. The plenum chamber is in communication with one or more of the compartments within the electrical enclosure, for example, via an exhaust chamber. The exhaust chamber is in adjacent communication with the plenum chamber. The plenum chamber provides an exit path for releasing pressure and gases generated by the electrical components and the electrical cables accommodated in the compartments during an event of arcing within the electrical enclosure. The switchgear assembly disclosed herein further comprises flaps positioned between the compartments and the plenum chamber for preventing the gases and external particulate matter from escaping the plenum chamber and entering into the compartments via the plenum chamber. The flaps isolate one or more of the compartments and the plenum chamber in the electrical enclosure. One of the compartments, for example, an upper compartment, is configured as a low voltage compartment for accommodating control equipment. In an embodiment, the low voltage compartment is isolated from the plenum chamber and other compartments, for example, the high voltage compartments in the switchgear assembly.

The mounting block assembly of the switchgear assembly disclosed herein is positioned in one or more of the compartments for mounting one or more of the electrical components and for providing front access to the mounted electrical components for inspection and maintenance. Each mounting block assembly in the switchgear assembly comprises a base mounting block, multiple mounting legs, and a mounting block cover. The mounting legs extend frontwardly from the base mounting block for mounting one or more of the electrical components and for allowing front access to the mounted electrical components. The mounting block cover is removably attached to the base mounting block for enclosing the mounted electrical components on the mounting legs. The mounting block cover is removable for providing front access to the mounted electrical components for inspection and maintenance. The mounting block assembly is configured to reduce temperature rise in the compartments.

The electrical components and the electrical cables are accommodated and electrically connected in predetermined positions in the compartments of the switchgear assembly for allowing front access and/or rear access to the electrical components, the electrical cables, the bus bars within the electrical enclosure for cable connections, and current transformers mounted on the mounting legs of the mounting block assembly. The electrical components are arranged in interchangeable configurations in the compartments within the electrical enclosure. The electrical components interchangeably accommodated in the compartments with the electrical enclosure comprise, for example, a circuit breaker, a control power transformer having one of multiple power ratings (kVA), an epoxy encapsulated potential transformer having one of multiple voltage levels (kV), current transformers having one or more of multiple current ratios, etc. Each current transformer mounted on a mounting leg of one mounting block assembly has the same current ratio, for example, 1200:5. The current transformers mounted on a mounting leg of another mounting block assembly in another section of the electrical enclosure may have a different current ratio, for example, 600:5 or 300:5.

In an embodiment, the circuit breaker is accommodated and electrically connected in the middle compartment defined, for example, in the first section of the electrical enclosure. The circuit breaker is electrically connected within the mounting block assembly. The circuit breaker contacts one or more of the bus bars via the mounting block assembly. The control power transformer is mounted and electrically connected in the middle compartment defined, for example, in the second section of the electrical enclosure and communicates with the other electrical components in the electrical enclosure via the mounting block assembly and one or more of the bus bars. In an embodiment, the epoxy encapsulated potential transformer is mounted and electrically connected in a middle compartment, or a lower compartment defined, for example, in the first section or the second section of the electrical enclosure and communicates with the other electrical components in the electrical enclosure via the mounting block assembly and one or more of the bus bars.

In an embodiment, the epoxy encapsulated potential transformer, the electrical cables, and the circuit breaker or the control power transformer are positioned in a single section of the switchgear assembly. For example, the epoxy encapsulated potential transformer can be positioned in the front lower compartment, the electrical cables can be positioned in the rear lower compartment, and the circuit breaker can be positioned in the middle compartment defined in the first section of the electrical enclosure. In another example, the epoxy encapsulated potential transformer can be positioned in the front lower compartment, the electrical cables can be positioned in the rear lower compartment, and the control power transformer can be positioned in the middle compartment defined in the second section of the electrical enclosure.

The switchgear assembly disclosed herein further comprises one or more fuse sleeve assemblies operably connected to each of the control power transformer and the epoxy encapsulated potential transformer. The fuse sleeve assemblies allow high voltage primary connections of the control power transformer and the epoxy encapsulated potential transformer in the electrical enclosure. The fuse sleeve assemblies provide insulating barriers between the high voltage primary connections and the electrical enclosure. The fuse sleeve assemblies operably connected to each of the control power transformer and the epoxy encapsulated potential transformer contact one or more of the bus bars, for example, in a rear compartment within the electrical enclosure via the mounting block assembly, thereby creating an ultra compact switchgear assembly. The fuse sleeve assemblies contact a cylindrical bus mounted in the mounting block assembly. The mounting block assembly is configured to accommodate each of the fuse sleeve assemblies of the control power transformer and the epoxy encapsulated potential transformer and to isolate phases of the control power transformer and the epoxy encapsulated potential transformer. The control power transformer and the epoxy encapsulated potential transformer comprise low voltage contacts configured to disengage from low voltage connections within the electrical enclosure for preventing an event of arcing. In an embodiment, insulating barriers are provided between high voltage primary connections and the electrical enclosure of the switchgear assembly for preventing exposure of active electrical components within the electrical enclosure.

In an embodiment, the current transformer is mounted in the mounting block assembly, for example, in a middle compartment within the electrical enclosure and adapted for saving space in the electrical enclosure. In an embodiment, the current transformers are mounted on an input and an output of the circuit breaker via the mounting block assembly. In an embodiment, a cord is electrically connected to the circuit breaker for low voltage connection within the electrical enclosure.

The input electrical cables and output electrical cables enter into and/or exit out from the electrical enclosure, for example, via an upper compartment, a front lower compartment, and/or a rear lower compartment in the electrical enclosure. The electrical cables are also interchangeably accommodated in the compartments, for example, the upper compartment, the front lower compartment, and/or the rear lower compartment within the electrical enclosure. The input electrical cables and the output electrical cables are accessible from the front side and/or the rear side of the switchgear assembly. One or more of the bus bars allow electrical communication between the electrical components within the electrical enclosure. One or more of the bus bars also electrically communicate with the electrical cables. The bus bars are electrically connected in the rear compartments within the electrical enclosure. In an embodiment, the bus bars comprise horizontal bus bars electrically connected in the rear compartments within the electrical enclosure. One or more of the horizontal bus bars allow connection to adjacent sections defined in the electrical enclosure, connection between one or more of the electrical components in the adjacent sections defined in the electrical enclosure, connection between the electrical cables in adjacent compartments in the electrical enclosure and in the adjacent sections defined in the electrical enclosure, and connection to one or more other switchgear assemblies. The multi-access switchgear assembly can be configured to line up with a switchgear having a current rating of, for example, about 2000 amperes, thereby enabling usage of circuit breakers having current ratings of, for example, about 1200 amperes and 2000 amperes in a single line up.

The switchgear assembly disclosed herein further comprises one or more infrared windows positioned at predetermined locations on a front side and/or a rear side of the switchgear assembly for front scanning and/or rear scanning of the electrical components, the electrical cables, and the bus bars in the compartments for inspection and maintenance. In an embodiment, support brackets are connected to the infrared windows for protecting the infrared windows from rupture. The switchgear assembly disclosed herein further comprises one or more inspection windows, for example, windows made of Lexan® of Saudi Basic Industries Corp, positioned at predetermined locations on the front side and/or the rear side of the switchgear assembly for providing a front visual indication and/or a rear visual indication of the electrical components, the electrical cables, and the bus bars for inspection and maintenance and for critical electrical high voltage connections.

The switchgear assembly disclosed herein further comprises surge arresters positioned, for example, in a rear compartment within the electrical enclosure. The surge arresters protect the electrical components, the bus bars, the mounting block assembly, the inspection windows, the infrared windows, the input electrical cables, the output electrical cables, and the compartments defined with the electrical enclosure in an event of a lightning surge. The surge arresters are electrically connected to one or more of the bus bars in the electrical enclosure via short high voltage electrical cables. The surge arresters are compact and represent a unique way to mount and connect them to make the switchgear assembly compact.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing summary, as well as the following detailed description of the invention, is better understood when read in conjunction with the appended drawings. For the purpose of illustrating the invention, exemplary constructions of the invention are shown in the drawings. However, the invention is not limited to the specific methods and instrumentalities disclosed herein.

FIG. 1A exemplarily illustrates a cut-away left perspective view of a front accessible switchgear assembly.

FIG. 1B exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly, showing a circuit breaker electrically connected in a middle compartment of the front accessible switchgear assembly.

FIG. 2 exemplarily illustrates a cut-away right perspective view of the front accessible switchgear assembly.

FIG. 3 exemplarily illustrates a cut-away rear perspective view of the front accessible switchgear assembly.

FIG. 4A exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly, showing surge arresters positioned in a rear compartment defined in a first section of an electrical enclosure of the front accessible switchgear assembly.

FIG. 4B exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly, showing support brackets for protecting infrared windows positioned on a rear side of the front accessible switchgear assembly.

FIG. 5 exemplarily illustrates a cut-away right perspective view of the front accessible switchgear assembly, showing a control power transformer electrically connected in a middle compartment and an epoxy encapsulated potential transformer electrically connected in a lower compartment of the front accessible switchgear assembly.

FIG. 6 exemplarily illustrates a left perspective view of the front accessible switchgear assembly.

FIG. 7 exemplarily illustrates a left orthogonal view of the front accessible switchgear assembly.

FIG. 8 exemplarily illustrates a front orthogonal view of the front accessible switchgear assembly, showing an infrared window and inspection windows positioned at predetermined locations on the front side of the front accessible switchgear assembly.

FIG. 9 exemplarily illustrates a rear perspective view of the front accessible switchgear assembly, showing infrared windows and inspection windows positioned at predetermined locations on the rear side of the front accessible switchgear assembly.

FIG. 10 exemplarily illustrates a bottom orthogonal view of the front accessible switchgear assembly, showing a front lower compartment of the front accessible switchgear assembly configured for enabling electrical cables to enter into and/or exit out from the electrical enclosure.

FIG. 11A exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly, showing a circuit breaker electrically connected in a middle compartment of the front accessible switchgear assembly.

FIG. 11B exemplarily illustrates a bottom orthogonal view of the front accessible switchgear assembly of FIG. 11A, showing the electrical cables entering into the electrical enclosure via the front lower compartment defined in the first section of the electrical enclosure.

FIG. 12 exemplarily illustrates a cut-away right orthogonal view of the front accessible switchgear assembly, showing a control power transformer electrically connected in a middle compartment and an epoxy encapsulated potential transformer electrically connected in a lower compartment of the front accessible switchgear assembly.

FIG. 13 exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly, showing the electrical cables electrically connected to the upper horizontal bus bars via cable connection bus bars.

FIGS. 14A-14B exemplarily illustrate cut-away left orthogonal views of a second section of the front accessible switchgear assembly, showing electrical connection of upper horizontal bus bars from a first section of the electrical enclosure to lower horizontal bus bars in the second section of the electrical enclosure via transitional bus bars.

FIG. 15 exemplarily illustrates a cut-away left orthogonal view of the first section of the front accessible switchgear assembly, showing the upper horizontal bus bars accommodated in a central compartment defined in the first section of the front accessible switchgear assembly and electrically connected to the lower horizontal bus bars that extend into the second section of the front accessible switchgear assembly, via mounting block assemblies with a mounted circuit breaker.

FIG. 16A exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly, showing an upper compartment of the front accessible switchgear assembly configured for enabling the electrical cables to enter into and/or exit out from the electrical enclosure, where the electrical cables are electrically connected to upper horizontal bus bars via cable connection bus bars.

FIG. 16B exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly, showing an upper compartment of the front accessible switchgear assembly configured for enabling the electrical cables to enter into and/or exit out from the electrical enclosure, and a support bracket for protecting an infrared window positioned on a front side of the front accessible switchgear assembly.

FIG. 16C exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly, showing an upper compartment of the front accessible switchgear assembly configured for enabling the electrical cables to enter into and/or exit out from the electrical enclosure, where the electrical cables are electrically connected to lower horizontal bus bars via cable connection bus bars.

FIG. 16D exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly, showing an upper compartment of the front accessible switchgear assembly configured for enabling the electrical cables to enter into and/or exit out from the electrical enclosure, and a support bracket for protecting an infrared window positioned on a front side of the front accessible switchgear assembly.

FIG. 17 exemplarily illustrates a cut-away left perspective view of a multi-access switchgear assembly, showing electrical cables accommodated in a rear lower compartment, a circuit breaker accommodated in a middle compartment, and an epoxy encapsulated potential transformer accommodated in a front lower compartment, in a single section of the multi-access switchgear assembly.

FIG. 18A exemplarily illustrates a cut-away left perspective view of the multi-access switchgear assembly, showing electrical cables accommodated in the rear lower compartment of the multi-access switchgear assembly and electrically connected to the upper horizontal bus bars via the cable connection bus bars.

FIG. 18B exemplarily illustrates a bottom orthogonal view of the multi-access switchgear assembly of FIG. 18A, showing the electrical cables entering into the electrical enclosure via the rear lower compartment of the multi-access switchgear assembly.

FIG. 19A exemplarily illustrates a cut-away left perspective view of the multi-access switchgear assembly, showing electrical cables accommodated in a front lower compartment and the rear lower compartment of the multi-access switchgear assembly.

FIG. 19B exemplarily illustrates a bottom orthogonal view of the multi-access switchgear assembly of FIG. 19A, showing the electrical cables entering into the electrical enclosure via the front lower compartment and the rear lower compartment of the multi-access switchgear assembly.

FIGS. 20A-20C exemplarily illustrate perspective views of a mounting block assembly for the front accessible switchgear assembly and the multi-access switchgear assembly.

FIGS. 21A-21B exemplarily illustrate perspective views of a circuit breaker utilized in the front accessible switchgear assembly and the multi-access switchgear assembly, showing tulip contacts of the circuit breaker.

FIG. 21C exemplarily illustrates a plan view showing connection of the circuit breaker within the mounting block assembly.

FIG. 21D exemplarily illustrates a sectional view taken at section A-A of FIG. 21C, showing connection of a tulip contact of the circuit breaker to a cylindrical bus that runs inside the mounting block assembly.

FIGS. 22A-22B exemplarily illustrate perspective views of a control power transformer comprising fuse sleeve assemblies utilized in the front accessible switchgear assembly and the multi-access switchgear assembly.

FIG. 22C exemplarily illustrates a perspective view of the control power transformer, showing an exploded view of one of the fuse sleeve assemblies operably connected to the control power transformer.

FIG. 22D exemplarily illustrates a plan view showing connection of the control power transformer to the mounting block assembly.

FIG. 22E exemplarily illustrates a sectional view taken at section B-B of FIG. 22D, showing connection of the control power transformer to a cylindrical bus that runs inside the mounting block assembly.

FIGS. 23A-23B exemplarily illustrate perspective views of an epoxy encapsulated potential transformer utilized in the front accessible switchgear assembly and the multi-access switchgear assembly.

FIG. 23C exemplarily illustrates a perspective view of the epoxy encapsulated potential transformer, showing an exploded view of one of the fuse sleeve assemblies operably connected to the epoxy encapsulated potential transformer.

FIG. 23D exemplarily illustrates a plan view showing connection of the epoxy encapsulated potential transformer to the mounting block assembly.

FIG. 23E exemplarily illustrates a sectional view taken at section C-C of FIG. 23D, showing connection of the epoxy encapsulated potential transformer to a cylindrical bus that runs inside the mounting block assembly.

FIG. 24 illustrates a method for constructing a front accessible switchgear assembly.

FIG. 25 illustrates a method for constructing a multi-access switchgear assembly.

DETAILED DESCRIPTION OF THE INVENTION

Disclosed herein is a compact arc resistant metal clad switchgear assembly that has a compact footprint and provides either front access only, or front access and rear access herein referred to as “multi-access”, to electrical components, electrical cables, equipment, etc., accommodated in the switchgear assembly for inspection, testing and maintenance with limited space requirements and without protective gear. The compact arc resistant metal clad switchgear assembly that provides front access only is herein referred to as a “front accessible switchgear assembly”. As used herein, the front accessible switchgear assembly 100, exemplarily illustrated in FIGS. 1A-16D, refers to a switchgear assembly 100 that allows access to electrical cables 111, electrical components 113, 118, 119, 120, etc., the bus bars 103, and equipment accommodated within the switchgear assembly 100 from the front side 100 a of the switchgear assembly 100 only. The compact arc resistant metal clad switchgear assembly that provides front access and/or rear access, that is, multi-access, is herein referred to as a “multi-access switchgear assembly”. As used herein, the multi-access switchgear assembly 1700, exemplarily illustrated in FIGS. 17-19B, refers to a switchgear assembly 1700 that allows access to the electrical cables 111, the electrical components 113, 118, 119, 120, etc., the bus bars 103, and equipment accommodated within the switchgear assembly 1700 from the front side 1700 a and/or the rear side 1700 b of the switchgear assembly 1700. As used herein, the electrical cables 111 comprise incoming electrical cables and outgoing electrical cables.

FIGS. 1A-1B exemplarily illustrate cut-away left perspective views of a front accessible switchgear assembly 100. The front accessible switchgear assembly 100 disclosed herein comprises a compact and arc resistant electrical enclosure 101, multiple compartments 102 defined within the electrical enclosure 101, one or more mounting block assemblies 104, a plenum chamber 105, electrical cables 111, electrical components 113, 118, 119, 120, etc., and bus bars 103. The front accessible switchgear assembly 100 disclosed herein is a metal clad switchgear assembly. Adjacent sections 101 a and 101 b defined in the electrical enclosure 101 of the front accessible metal clad switchgear assembly 100 are separated by vertical metal barriers 101 c for compartmentalizing active electrical components 118, 119, 120, etc., in the electrical enclosure 101. The front accessible metal clad switchgear assembly 100 has a higher duty cycle and a greater number of load operations, for example, about 10 times to about 1000 times greater number of load operations than that of a metal enclosed switchgear assembly. The “front accessible metal clad switchgear assembly” is herein referred to as a “front accessible switchgear assembly”.

The size of the front accessible switchgear assembly 100 disclosed herein is configured to ensure space savings and easy access from the front side 100 a of the front accessible switchgear assembly 100. The front accessible switchgear assembly 100 disclosed herein refers to a 15000 volts (V) switchgear assembly and can be extended to higher and lower voltages. The front accessible switchgear assembly 100 disclosed herein accommodates 15 kilovolt (kV) class equipment and provides solutions for 95 kV lightning impulse voltage and 1200 ampere (A) rating with a control power transformer 119, exemplarily illustrated in FIG. 2, rated up to 15 kVA. The front accessible switchgear assembly 100 disclosed herein can be extended to higher ratings and can be used for low voltage switchgear assemblies rated 600V and below.

The compartments 102 are configured to interchangeably accommodate one or more electrical components, for example, a control power transformer 119 having one of multiple power ratings (kVA), one or more current transformers 113 having one or more of multiple current ratios, a circuit breaker 118, an epoxy encapsulated potential transformer 120 having one of multiple voltage levels (kV), etc., input and output electrical cables 111 herein referred to as “electrical cables”, and bus bars 103, for example, upper horizontal bus bars 103 a, lower horizontal bus bars 103 d exemplarily illustrated in FIG. 2, cable connection bus bars 103 c, etc.

The electrical enclosure 101 of the front accessible switchgear assembly 100 exemplarily illustrated in FIGS. 1A-1B, FIGS. 2-6, and FIGS. 8-10 is divided into two sections, for example, a first section 101 a and a second section 101 b. The front accessible switchgear assembly 100 disclosed herein is a compact basic two section switchgear assembly 100. For front accessibility in the front accessible switchgear assembly 100, each of the sections 101 a and 101 b of the electrical enclosure 101 is configured, for example, 23.62 inches wide, 60 inches deep, and 96 inches high to provide all basic functions and components needed in the front accessible switchgear assembly 100. For front and rear accessibility in the multi-access switchgear assembly 1700 exemplarily illustrated in FIG. 17, FIG. 18A, and FIG. 19A, each of the sections 101 a and 101 b of the electrical enclosure 101 is configured, for example, 23.62 inches wide, 72 inches deep, and 96 inches high to provide all basic functions and components needed in the multi-access switchgear assembly 1700. The increased depth of the multi-access switchgear assembly 1700 enables accommodation of electrical equipment, for example, circuit breakers 118 with high current ratings ranging from 1200 A to about 2000 A. Moreover, the multi-access switchgear assembly 1700 with its larger volume can accommodate two circuit breakers 118 with different current ratings, for example, a first circuit breaker 118 with a current rating of 1200 A and a second circuit breaker 118 with a current rating of 2000 A.

The compartments 102 comprising, for example, upper compartments 102 a, middle compartments 102 b, lower compartments 102 c, a central compartment 102 d, rear compartments 102 e, etc., are defined in the first section 101 a and the second section 101 b of the electrical enclosure 101. For example, the first section 101 a of the electrical enclosure 101 defines one of the upper low voltage compartments 107, one of the middle compartments 102 b, one of the lower compartments 102 c, the central compartment 102 d, and one of the rear compartments 102 e.

The first section 101 a of the electrical enclosure 101 also accommodates the plenum chamber 105. The plenum chamber 105 is rearwardly positioned in the electrical enclosure 101. The plenum chamber 105 is an open space for hot gases to escape from the electrical enclosure 101 to the outside environment, for example, via a venting duct system of a building. The plenum chamber 105 comprises a flange 105 a that provides an exit path for the gases to escape. The flange 105 a is connected to the venting duct system for exhausting the gases. The flange 105 a is configured as a perforated plate, a thin sheet metal plate, or an aluminum plate with flaps, which prevents the entry of gases, external particulate matter, etc., into the electrical enclosure 101 from the venting duct system of the building. The plenum chamber 105 provides a large space for hot gases to expand and allows safe exhaust of, for example, arcs, in an event of arcing. The safe exhaust of hot gases and arcs ensure safety of personnel working around the electrical enclosure 101 of the front accessible switchgear assembly 100. The plenum chamber 105 is made of the same material, for example, sheet metal, as the compartments 102. The plenum chamber 105 is in communication with one or more of the compartments 102 and provides an exit path for releasing pressure and gases generated by the electrical cables 111 and the electrical components 113, 118, 119, 120, etc., accommodated in the compartments 102 during an event of arcing within the electrical enclosure 101.

The plenum chamber 105 communicates with one or more of the compartments 102 via an exhaust chamber 112 in adjacent communication with the plenum chamber 105. The exhaust chamber 112 extends from the first section 101 a through to the second section 101 b of the electrical enclosure 101. The plenum chamber 105 is rearwardly positioned to connect to venting ducts of a building to exhaust the gases to the outside environment safely during an arcing event. The plenum chamber 105 may be positioned to the left or the right of the front accessible switchgear assembly 100 and may be connected to the venting ducts that go in an upward direction or a downward direction based on typical design practices.

The front accessible switchgear assembly 100 efficiently exhausts the gases and the pressure from the compartments 102 to the plenum chamber 105 during an arcing event without creating excessive pressure in the compartments 102. The compartments 102 of the front accessible switchgear assembly 100 are configured to minimize the pressure of gases during an arcing event. The front accessible switchgear assembly 100 disclosed herein further comprises flaps 106 a, 106 b, and 106 c positioned between one or more of the compartments 102 and the plenum chamber 105 for preventing the gases, external particulate matter, and other external elements from entering the compartments 102 via the plenum chamber 105. The flaps 106 a, 106 b, and 106 c are configured as perforated plates for allowing gases to exit into the plenum chamber 105. For example, the flaps 106 a are positioned at the top of the central compartment 102 d defined in the first section 101 a of the electrical enclosure 101, and at the top of the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101. Furthermore, the flaps 106 b and 106 c are provided for the exhaust chamber 112 and the middle compartment 102 b respectively as exemplarily illustrated in FIG. 1A. The flaps 106 a and 106 b delineate the exhaust chamber 112 within the electrical enclosure 101.

The flaps 106 a, 106 b, and 106 c are made of a thin metal or aluminum and if there is an arcing event and the pressure of gases in the compartments, for example, 102 b, 102 c, and 102 d becomes high, one or more of the flaps 106 a, 106 b, and 106 c open to allow the gases to exhaust to the plenum chamber 105. For example, if there is an arcing event in the central compartment 102 d, the gases exit to the plenum chamber 105 through one or more of the flaps 106 a. In the event of arcing in the lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101 that accommodates the electrical cables 111 exemplarily illustrated in FIG. 1A, gases from the lower compartment 102 c exit, for example, through the rear compartment 102 e and into the plenum chamber 105 via one of the flaps 106 a. If an electrical component, for example, an epoxy encapsulated potential transformer 120 is positioned in the lower compartment 102 c defined in the second section 101 b of the electrical enclosure 101 as exemplarily illustrated in FIG. 2, the gases exit, for example, through the flap 106 c exemplarily illustrated in FIG. 1A, FIG. 16B, and FIG. 16D and into the plenum chamber 105, for example, via the flap 106 b of the exhaust chamber 112. In the event of arcing in the middle compartment 102 b, the gases exit from the middle compartment 102 b to the exhaust chamber 112, for example, via the flap 106 b and thereafter to the plenum chamber 105.

One or more of the compartments 102, for example, the upper compartments 102 a are configured as low voltage compartments 107 for accommodating control equipment (not shown). In an embodiment, the middle compartments 102 b and the lower compartments 102 c can be configured as low voltage compartments 107. The control equipment in the low voltage compartment 107 is employed for relay and protection and comprises relay equipment, for example, overcurrent relays, differential relays, under voltage relays, ground fault relays, protection relays, under frequency relays, integrated digital relays such as Schweitzer relays and Bassler relays, etc. The control equipment in the low voltage compartment 107 further comprises programmable logic controllers for performing control functions, human machine interfaces for performing display functions, metering equipment for measurement and display of voltage, current, frequency, etc., and other control equipment for motor control, etc. The control equipment provides protection against current and voltage fluctuations, for example, over current, undercurrent, differential voltages, ground fault, etc. The control equipment provides protection against changes in frequency, for example, under frequency, etc.

Control switches and push buttons are also provided on the low voltage compartment 107. In an embodiment, control functions of the circuit breaker 118 can be incorporated in the low voltage compartment 107. A cord 118 a configured, for example, as an umbilical cord, is electrically connected to the circuit breaker 118 for low voltage connection within the electrical enclosure 101. The cord 118 a makes the low voltage connection via a connector 118 b, for example, a male connector as exemplarily illustrated in FIGS. 21A-21B. The outputs of the electrical components, for example, the current transformer 113, the epoxy encapsulated potential transformer 120, and the control power transformer 119 can also be integrated in the low voltage compartment 107 for control, protection and display functions. The control equipment in the low voltage compartment 107 communicates with other control equipment in the front accessible switchgear assembly 100 or other external control equipment, for example, by communication protocols such as Ethernet, Modbus, serial link, etc.

The low voltage compartment 107 is isolated from the plenum chamber 105 and the other compartments 102 defined in the electrical enclosure 101. In an embodiment, the low voltage compartment 107 can be configured in the upper compartment 102 a and isolated from the middle compartment 102 b, the lower compartment 102 c, and the rear compartment 102 e. In another embodiment, the low voltage compartment 107 can be configured as a complete section comprising the upper compartment 102 a, the middle compartment 102 b, and the lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101 and is isolated from the high voltage rear compartments 102 e, for example, by sheet metal barriers. In this embodiment, the low voltage compartment 107 is a full section extending from the upper compartment 102 a to the lower compartment 102 c and encompassing the middle compartment 102 b. If the low voltage compartment 107 is configured as a complete section and used for control, the electrical cables 111, the electrical components 113, 118, 119, 120, etc., and the bus bars 103 are separated by metal barriers. High voltage electrical components positioned in the central compartment 102 d and the rear compartment 102 e are isolated from the low voltage compartment 107, for example, by sheet metal barriers.

The upper low voltage compartment 107 is isolated from the plenum chamber 105 and there is no communication between the upper low voltage compartment 107 and the plenum chamber 105. By sealing the upper low voltage compartment 107 from the other high voltage compartments 102 b, 102 c, 102 d, and 102 e and the plenum chamber 105, arc rating can be obtained for the front accessible switchgear assembly 100, where it is possible to open the upper low voltage compartment 107 when the front accessible switchgear assembly 100 is energized, without protective clothing for maintenance of low voltage control circuits. This is applied in, for example, a data center, health care, and other critical facilities. Significant arcing does not happen in the upper low voltage compartment 107 since the available power is very low. The configuration and functioning of the compartments 102, the low voltage compartment 107, the plenum chamber 105, the exhaust chamber 112, and the flaps 106 a, 106 b, and 106 c of the front accessible switchgear assembly 100 exemplarily illustrated in FIGS. 1A-16D also apply to the multi-access switchgear assembly 1700 exemplarily illustrated in FIGS. 17-19B.

The electrical cables 111 and the electrical components 113, 118, 119, 120, etc., are electrically connected in predetermined positions in the compartments 102 for allowing front access and/or rear access to the electrical cables 111, the electrical components 113, 118, 119, 120, etc., and the bus bars 103 within the electrical enclosure 101. In the front accessible switchgear assembly 100 as exemplarily illustrated in FIGS. 1A-16D, the electrical cables 111 and the electrical components 113, 118, 119, 120, etc., are accessible only from the front side 100 a of the front accessible switchgear assembly 100. One or more of the electrical cables 111 and the electrical components 113, 118, 119, 120, etc., are in electrical communication with one or more of the bus bars 103 in one or more of the compartments 102. The bus bars 103 are electrically connected in the rear compartments 102 e defined in the first section 101 a and the second section 101 b of the electrical enclosure 101. The configuration and functioning of the electrical components 113, 118, 119, 120, etc., and the bus bars 103 of the front accessible switchgear assembly 100 exemplarily illustrated in FIGS. 1A-16D also apply to the multi-access switchgear assembly 1700 exemplarily illustrated in FIGS. 17-19B. In the multi-access switchgear assembly 1700 exemplarily illustrated in FIGS. 17-19B, the electrical components 113, 118, 119, 120, etc., are accessible from the front side 1700 a of the multi-access switchgear assembly 1700, while the electrical cables 111 and one or more of the bus bars 103 are accessible from the front side 1700 a and/or the rear side 1700 b of the multi-access switchgear assembly 1700 as exemplarily illustrated in FIGS. 17-19B.

The mounting block assembly 104 utilized in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 is positioned in one or more of the compartments 102, for example, the middle compartments 102 b, the central compartment 102 d, etc., defined in the electrical enclosure 101. The mounting block assembly 104 for mounting one or more of the electrical components, for example, the current transformers 113, the circuit breaker 118, etc., is disclosed in the detailed description of FIGS. 20A-20C. The mounting block assembly 104 provides front access to the mounted electrical components 113, 118, 119, 120, etc., for inspection and maintenance. In an embodiment, the mounting block assembly 104 is configured as a two-part assembly to increase creepage distance resulting in a compact front accessible switchgear assembly 100 and a compact multi-access switchgear assembly 1700.

One of the electrical components, for example, the circuit breaker 118 is electrically connected in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101 as exemplarily illustrated in FIG. 1B. The construction of the circuit breaker 118 is disclosed in the detailed description of FIGS. 21A-21B. The circuit breaker 118 comprises tulip contacts 118 f provided on arms 118 c extending outwardly from the circuit breaker 118 as exemplarily illustrated in FIGS. 21A-21B. The tulip contacts 118 f of the circuit breaker 118 connect to a cylindrical bus 104 c made of, for example, copper, that runs inside the mounting block assembly 104 as exemplarily illustrated in FIG. 21D, in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101.

As exemplarily illustrated in FIGS. 1A-1B, FIG. 3, FIGS. 4A-4B, FIG. 10, FIGS. 11A-11B, FIG. 13, and FIGS. 16A-16D, one or more of the compartments 102 a, 102 c, etc., defined in the first section 101 a of the electrical enclosure 101 are configured for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101 for allowing only front access to the electrical cables 111. In an embodiment, the electrical cables 111 are accommodated in a front lower compartment 102 c defined in the second section 101 b of the electrical enclosure 101. The front accessible switchgear assembly 100 enables the accommodation and electrical connection of the electrical cables 111 in a single compartment, for example, the front lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101. The ability to accommodate three phases of the electrical cables 111 in a single compartment, for example, the front lower compartment 102 c provides an ultra compact set up for the circuit breaker 118 as part of the front accessible switchgear assembly 100, thereby minimizing the requirement of additional sections or compartments 102.

The front accessible switchgear assembly 100 disclosed herein further comprises multiple surge arresters 116, for example, typically one for each phase of the circuit of the front accessible switchgear assembly 100. The surge arresters 116 are positioned, for example, in the rear compartments 102 e defined in the electrical enclosure 101 for protecting the electrical components 113, 118, 119, 120, etc., the bus bars 103, inspection windows 109, infrared windows 108, the electrical cables 111, the mounting block assembly 104, the compartments 102 defined within the electrical enclosure 101, etc., in an event of a lightning surge. As exemplarily illustrated in FIGS. 1A-1B, FIGS. 3-5, and FIG. 11A, the surge arresters 116 are positioned in a rear lower compartment 102 e defined in the first section 101 a of the electrical enclosure 101. The surge arresters 116 protect the electrical cables 111, the electrical components 113, 118, 119, 120, etc., the bus bars 103, the mounting block assembly 104, the compartments 102, etc., from damaging voltages generated during a lightning surge.

The surge arresters 116 are electrically connected to one or more of the bus bars 103, for example, the cable connection bus bars 103 c in the electrical enclosure 101 via short high voltage electrical cables 110. The short high voltage electrical cables 110 provide, for example, a lower electrical inductance that limits clamping voltage of the surge arresters 116 more effectively within the electrical enclosure 101, thereby increasing the effectiveness of the surge arresters 116. The clamping voltage is the maximum amount of voltage that a surge arrester 116 allows through it before the surge arrester 116 suppresses a power surge. The surge arresters 116 suppress the power surge by diverting the power to ground or by absorbing the excess energy. In an embodiment, the base of the surge arresters 116 is grounded to the electrical enclosure 101, for example, by creating metal to metal contact by making the mounting surface free of paint. In another embodiment, a cable (not shown) can be used to make the grounding connection to the surge arresters 116. The surge arresters 116 are compact and are mounted and connected within the electrical enclosure 101 to make the front accessible switchgear assembly 100 disclosed herein compact.

The bus bars 103 comprising, for example, upper horizontal bus bars 103 a are electrically connected in the rear compartment 102 e defined in the first section 101 a of the electrical enclosure 101. The bus bars 103 are strips of conducting materials, for example, copper, aluminum, etc., that conduct electricity within the front accessible switchgear assembly 100. One or more of the horizontal bus bars 103 a and 103 d exemplarily illustrated in FIGS. 1A-1B and FIG. 2, allow connection to adjacent sections 101 a and 101 b defined in the electrical enclosure 101, connection between the electrical components 119, 120, etc., in the adjacent sections 101 a and 101 b defined in the electrical enclosure 101, connection between the electrical cables 111 in adjacent compartments 102 in the electrical enclosure 101 and in the adjacent sections 101 a and 101 b defined in the electrical enclosure 101, and connection to one or more other switchgear assemblies. The second section 101 b of the electrical enclosure 101 is exemplarily illustrated in FIG. 2.

The control power transformer 119 and the epoxy encapsulated potential transformer 120 are electrically connected to the cylindrical bus 104 c that runs inside the mounting block assembly 104, for example, via the fuse sleeve assemblies 119 a and 120 a of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively as exemplarily illustrated in FIG. 22E and FIG. 23E respectively. The fuse sleeve assemblies 119 a and 120 a of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively contact one or more of the bus bars 103 in the rear compartment 102 e within the electrical enclosure 101 via the cylindrical bus 104 c in the mounting block assembly 104 and high voltage electrical cables (not shown). The mounting block assembly 104 is configured to accommodate each of the fuse sleeve assemblies 119 a and 120 a of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively and to isolate phases of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively.

The front accessible switchgear assembly 100 disclosed herein further comprises one or more infrared windows 108 and inspection windows 109 positioned at predetermined locations on the front side 100 a and/or the rear side 100 b of the front accessible switchgear assembly 100, as exemplarily illustrated in FIGS. 1A-1B and FIG. 4B, for inspection and maintenance. The infrared windows 108 and the inspection windows 109 are disclosed in the detailed description of FIG. 4B and FIG. 8. The front accessible switchgear assembly 100 disclosed herein further comprises cable bushings 117 positioned in the rear compartment 102 e and configured on a barrier 101 c between the adjacent sections 101 a and 101 b of the electrical enclosure 101. The cable bushings 117 are provided for receiving cables that connect the electrical components 119, 120, etc., positioned in one adjacent section 101 b of the electrical enclosure 101 to the bus bars 103 positioned in the other adjacent section 101 a of the electrical enclosure 101. For example, the cable bushings 117 receive cables that connect the control power transformer 119 and the epoxy encapsulated potential transformer 120 in the second section 101 b of the electrical enclosure 101 to the horizontal bus bars 103 a or the cable connection bus bars 103 c in the first section 101 a of the electrical enclosure 101.

The front accessible switchgear assembly 100 is compact and is configured with a depth of, for example, about 60 inches for front access only. The width and height of each of the sections 101 a and 101 b of the electrical enclosure 101 of the front accessible switchgear assembly 100 are, for example, about 23.62 inches and about 96 inches respectively. A front working clearance of, for example, about five feet is required for the front accessible switchgear assembly 100. In the case of the front accessible switchgear assembly 100, no working clearance is required in the rear and therefore the front accessible switchgear assembly 100 is effectively utilized for installations with limited spaces.

The electrical cables 111 may be connected in the lower compartment 102 c. The circuit breaker 118 and the control power transformer 119 are mounted in the middle compartment 102 b in the adjacent sections 101 a and 101 b of the electrical enclosure 101 respectively. The epoxy encapsulated potential transformer 120 may be mounted in the lower compartment 102 c or in the middle compartment 102 b. In an embodiment as exemplarily illustrated in FIG. 3, the electrical cables 111 are connected in the front lower compartment 102 c of the first section 101 a, while the epoxy encapsulated potential transformer 120 is mounted in the lower compartment 102 c of the second section 101 b of the electrical enclosure 101.

The different compartments 102 that accommodate, for example, the epoxy encapsulated potential transformer 120, the control power transformer 119, the circuit breaker 118, the electrical cables 111, etc., can be interlocked using mechanical Kirk® keys of the Kirk Key Interlock Company or may be interlocked electrically so that the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 are safe from a maintenance and user standpoint using standard schemes.

FIG. 2 exemplarily illustrates a cut-away right perspective view of the front accessible switchgear assembly 100. FIG. 2 illustrates the second section 101 b of the electrical enclosure 101. The second section 101 b of the electrical enclosure 101 defines, for example, one of the upper low voltage compartments 107, one of the middle compartments 102 b, one of the lower compartments 102 c, one of the rear compartments 102 e, and the exhaust chamber 112 extending from the first section 101 a through to the second section 101 b of the electrical enclosure 101. The upper low voltage compartment 107 accommodates the control equipment and is isolated from the middle compartments 102 b, the lower compartments 102 c, the central compartment 102 d, and the rear compartments 102 e.

The compartments 102 interchangeably accommodate one or more of the electrical components 118, 119, 120, etc. For example, the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101 accommodates the control power transformer 119. The control power transformer 119 is electrically connected in the middle compartment 102 b via the mounting block assembly 104 as exemplarily illustrated in FIG. 2. The fuse sleeve assemblies 119 a of the control power transformer 119 contact one or more of the bus bars 103 in the rear compartment 102 e within the electrical enclosure 101, for example, via the mounting block assembly 104 and high voltage electrical cables (not shown). The construction of the control power transformer 119 is disclosed in the detailed description of FIGS. 22A-22C. The lower compartment 102 c defined in the second section 101 b of the electrical enclosure 101 accommodates the epoxy encapsulated potential transformer 120. The epoxy encapsulated potential transformer 120 is electrically connected in the lower compartment 102 c as exemplarily illustrated in FIG. 2. In an embodiment, the epoxy encapsulated potential transformer 120 is electrically connected in the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101. The construction of the epoxy encapsulated potential transformer 120 is disclosed in the detailed description of FIGS. 23A-23C. Mounting and electrically connecting the epoxy encapsulated potential transformer 120 in either the lower compartment 102 c or the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101 enables creation of an ultra low footprint front accessible switchgear assembly 100 and an ultra low footprint multi-access switchgear assembly 1700. The fuse sleeve assemblies 120 a of the epoxy encapsulated potential transformer 120 contact one or more of the bus bars 103 in the rear compartment 102 e within the electrical enclosure 101, for example, via the mounting block assembly 104 and high voltage electrical cables (not shown).

The bus bars 103 comprising, for example, the upper horizontal bus bars 103 a and lower horizontal bus bars 103 d are electrically connected in the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101. The lower horizontal bus bars 103 d allow connection to one or more other switchgear assemblies. The upper horizontal bus bars 103 a are electrically connected to the lower horizontal bus bars 103 d via transitional bus bars 103 b disposed in the second section 101 b of the electrical enclosure 101.

FIG. 3 exemplarily illustrates a cut-away rear perspective view of the front accessible switchgear assembly 100. FIG. 3 illustrates the connection of the cable connection bus bars 103 c from the mounting block assembly 104 to the electrical cables 111 accommodated in the lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101. The cable connection bus bars 103 c are staggered for ease of electrical connection to the electrical cables 111 accommodated in the lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101. FIG. 3 also illustrates the bus bars 103 electrically connected in the second section 101 b of the electrical enclosure 101. The lower horizontal bus bars 103 d extend outwardly from the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101 for allowing connection to one or more other switchgear assemblies.

The compartments 102 defined in the first section 101 a and the second section 101 b of the electrical enclosure 101 are separated by barriers 101 c made of, for example, sheet metal. The components of the basic two section front accessible switchgear assembly 100 may be combined to form a long switchgear assembly line up. For example, the bus bars 103, for example, the upper horizontal bus bars 103 a and the lower horizontal bus bars 103 d allow connection of multiple switchgear assemblies to form a long switchgear assembly line up as the horizontal bus bars 103 a and 103 d line up either at the upper part or the lower part of the rear compartments 102 e defined in the first section 101 a and the second section 101 b of the electrical enclosure 101. The two section front accessible switchgear assembly 100 is flexibly configured to adapt to any switchgear assembly line up in multiple applications. The upper horizontal bus bars 103 a and the lower horizontal bus bars 103 d go through window bushings 114 and rest on the window bushings 114 so that it is easy to make connections since the weight of the horizontal bus bars 103 a and 103 d is carried by the window bushings 114. Small sections of, for example, epoxy coated bus bars, insulated bus bars with Raychem, or any other suitable insulation, etc., can easily join the horizontal bus bars 103 a and 103 d from two adjacent sections of the switchgear assemblies. Ground bus bars (not shown) in the lower compartment 102 c may also be connected on the front side 100 a of the front accessible switchgear assembly 100 using, for example, small copper bus bars. The configuration and functioning of the bus bars 103 of the front accessible switchgear assembly 100 exemplarily illustrated in FIGS. 1A-16D also apply to the multi-access switchgear assembly 1700 exemplarily illustrated in FIGS. 17-19B.

In an embodiment, the front accessible switchgear assembly 100 further comprises insulating boots 123 that provide additional insulation which increases creepage distance and helps in withstanding lightning impulses over time as insulators degrade. The insulating boots 123 are flexible boot like covers that enclose exposed bus bars 103 in the front accessible switchgear assembly 100. The insulating boots 123 therefore help maintain long-term reliability of the front accessible switchgear assembly 100. The configuration and functioning of the insulating boots 123 of the front accessible switchgear assembly 100 also apply to the multi-access switchgear assembly 1700 as disclosed in the detailed description of FIG. 17.

FIG. 4A exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly 100, showing surge arresters 116 positioned in a rear compartment 102 e defined in the first section 101 a of the electrical enclosure 101 of the front accessible switchgear assembly 100. The surge arresters 116 are electrically connected to the bus bars 103, for example, the cable connection bus bars 103 c in the electrical enclosure 101 via short high voltage electrical cables 110. The circuit breaker 118 is electrically connected in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101. A cord 118 a is electrically connected to the circuit breaker 118 for low voltage connection within the electrical enclosure 101. For example, the cord 118 a electrically connects the circuit breaker 118 to the control equipment in the upper low voltage compartment 107 defined in the first section 101 a of the electrical enclosure 101. The low voltage connection comprises electrical connection of a controller to the circuit breaker 118 for communicating open/close command signals to the circuit breaker 118, connection of auxiliary contacts that indicate open/close status of the circuit breaker 118, breaker interlocks that prevent closing of the circuit breaker 118 if the circuit breaker 118 is not fully racked into the middle compartment 102 b, connections to breaker under voltage relays and other associated breaker auxiliary components, etc.

FIG. 4A also illustrates the lower horizontal bus bars 103 d extending outwardly from the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101 for allowing connection to one or more other switchgear assemblies. In an embodiment, support brackets 121 protect the inspection windows 109 positioned on the front side 100 a of the front accessible switchgear assembly 100 from rupture. A support bracket 121 protecting an inspection window 109 and an infrared window 108 on the front side 100 a and/or the rear side 100 b of the front accessible switchgear assembly 100 is exemplarily illustrated in FIGS. 4A-4B, FIG. 16B, and FIG. 16D.

FIG. 4B exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly 100, showing support brackets 121 for protecting the infrared windows 108 positioned on a rear side 100 b of the front accessible switchgear assembly 100. The infrared window 108 positioned on a rear side 100 b of the front accessible switchgear assembly 100 allows rear scanning of, for example, the bus bars 103 in the rear compartment 102 e defined in the electrical enclosure 101 for inspection and maintenance. The inspection windows 109 positioned on a rear side 100 b of the front accessible switchgear assembly 100 provides a rear visual indication of, for example, the bus bars 103 in the rear compartment 102 e defined in the electrical enclosure 101 for inspection and maintenance.

FIG. 5 exemplarily illustrates a cut-away right perspective view of the front accessible switchgear assembly 100, showing a control power transformer 119 electrically connected in a middle compartment 102 b and an epoxy encapsulated potential transformer 120 electrically connected in a lower compartment 102 c of the front accessible switchgear assembly 100. FIG. 5 also illustrates the electrical connection of the upper horizontal bus bars 103 a to the lower horizontal bus bars 103 d via the transitional bus bars 103 b disposed in the second section 101 b of the electrical enclosure 101.

FIG. 6 and FIG. 7 exemplarily illustrate a left perspective view and a left orthogonal view of the front accessible switchgear assembly 100 respectively. Each of the compartments 102 accessible from the front side 100 a of the front accessible switchgear assembly 100 are provided with doors 115 that can be opened for allowing front access to the electrical cables 111, the electrical components 113, 118, 119, 120, etc., and the bus bars 103 for inspection and maintenance. The plenum chamber 105 is rearwardly positioned in the first section 101 a of the electrical enclosure 101 as disclosed in the detailed description of FIG. 1.

FIG. 8 exemplarily illustrates a front orthogonal view of the front accessible switchgear assembly 100, showing an infrared window 108 and inspection windows 109 positioned at predetermined locations on the front side 100 a of the front accessible switchgear assembly 100. Doors 115 are provided for accessing the compartments 102 defined in the first section 101 a and the second section 101 b of the electrical enclosure 101. The infrared windows 108 and the inspection windows 109 are operably positioned on the doors 115 of each of the compartments 102 on the front side 100 a of the front accessible switchgear assembly 100. The infrared windows 108 allow front scanning of the electrical cables 111, the electrical components 118, 119, etc., and the bus bars 103 in the compartments 102 for inspection and maintenance. The infrared windows 108 allow an infrared scan for any signs of overheating of the electrical components, for example, the circuit breaker 118, the electrical cables 111, and the bus bars 103, without the requirement of protective gear or clothing. The infrared windows 108 disclosed herein do not rupture during arc testing.

The inspection windows 109, for example, windows made of Lexan® of Saudi Basic Industries Corp, provide a front visual indication of the electrical cables 111, the electrical components 113, 118, 119, 120, etc., and the bus bars 103 in the compartments 102 for signs of heating of the electrical cables 111, the electrical components 113, 118, 119, 120, etc., and the bus bars 103 or any other abnormal conditions. Lexan® is a polycarbonate resin thermoplastic material manufactured by Saudi Basic Industries Corp used to construct the inspection windows 109 for the front accessible switchgear assembly 100. The inspection windows 109 provide an indication of a malfunction of any of the electrical cables 111, the electrical components 113, 118, 119, 120, etc. For example, the inspection windows 109 provide indications of the circuit breaker 118 from the front side 100 a of the front accessible switchgear assembly 100. In an embodiment, the central compartment 102 d is, for example, covered with an inspection window 109 made of Lexan®. The support brackets 121 protect the infrared windows 108 and the inspection windows 109 from rupture.

FIG. 9 exemplarily illustrates a rear perspective view of the front accessible switchgear assembly 100, showing infrared windows 108 and inspection windows 109 positioned at predetermined locations on the rear side 100 b of the front accessible switchgear assembly 100. The infrared windows 108 positioned on the rear side 100 b of the front accessible switchgear assembly 100 allow rear scanning of, for example, the bus bars 103 in the rear compartments 102 e, as exemplarily illustrated in FIG. 4B, defined in the first section 101 a and the second section 101 b of the electrical enclosure 101 for inspection and maintenance. The inspection windows 109 positioned on the rear side 100 b of the front accessible switchgear assembly 100 provides a rear visual indication of, for example, the bus bars 103 in the rear compartments 102 e, as exemplarily illustrated in FIG. 4B, defined in the first section 101 a and the second section 101 b of the electrical enclosure 101 for inspection and maintenance.

FIG. 10 exemplarily illustrates a bottom orthogonal view of the front accessible switchgear assembly 100, showing a front lower compartment 102 c of the front accessible switchgear assembly 100 configured for enabling electrical cables 111 to enter into and/or exit out from the electrical enclosure 101. The bottom of the front lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101 comprises cable entry and exit windows 122 that allow the electrical cables 111 to enter into and/or exit out from the front lower compartment 102 c of the front accessible switchgear assembly 100. In this embodiment, the front accessible switchgear assembly 100 allows front access to the electrical cables 111 accommodated in the front lower compartment 102 c of the front accessible switchgear assembly 100.

FIG. 11A exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly 100, showing a circuit breaker 118 electrically connected in a middle compartment 102 b of the front accessible switchgear assembly 100. FIG. 11A also illustrates the upper horizontal bus bars 103 a electrically connected in the central compartment 102 d defined in the first section 101 a of the electrical enclosure 101. Tulip contacts 118 f connected to the arms 118 c of the circuit breaker 118 are mounted in the mounting block assembly 104, when the circuit breaker 118 is racked in the middle compartment 102 b. The tulip contacts 118 f of the circuit breaker 118 contact a cylindrical bus 104 c running inside the mounting block assembly 104 as exemplarily illustrated in FIG. 21D. As exemplarily illustrated in FIG. 11A, the front accessible switchgear assembly 100 comprises two mounting block assemblies 104 for accommodating incoming circuit breaker connections 118 e and outgoing circuit breaker connections 118 d. The current transformers 113 are mounted on both the mounting block assemblies 104 that accommodate the incoming circuit breaker connections 118 e and the outgoing circuit breaker connections 118 d.

FIG. 11B exemplarily illustrates a bottom orthogonal view of the front accessible switchgear assembly 100 of FIG. 11A, showing the electrical cables 111 entering into the electrical enclosure 101 via the front lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101. The bottom of the front lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101 comprises cable entry and exit windows 122 that allow the electrical cables 111 to enter into and/or exit out from the front lower compartment 102 c of the front accessible switchgear assembly 100.

As exemplarily illustrated in FIG. 11A, the cable connection bus bars 103 c extend from the mounting block assembly 104 to the electrical cables 111 electrically connected in the front lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101. When the electrical cables 111 are electrically connected in the front lower compartment 102 c, the front lower compartment 102 c and the rear compartment 102 e defined in the first section 101 a of the electrical enclosure 101 are essentially a single compartment with no sheet metal barriers 101 e. In an embodiment, where an electrical component, for example, the epoxy encapsulated potential transformer 120, is mounted in the front lower compartment 102 c, the front lower compartment 102 c and the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101 are separated by barriers 101 e as exemplarily illustrated in FIG. 12.

FIG. 12 exemplarily illustrates a cut-away right orthogonal view of the front accessible switchgear assembly 100, showing a control power transformer 119 electrically connected in a middle compartment 102 b and an epoxy encapsulated potential transformer 120 electrically connected in a lower compartment 102 c of the front accessible switchgear assembly 100. Upper horizontal bus bars 103 a disposed in the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101 are connected to the lower horizontal bus bars 103 d via the transitional bus bars 103 b. FIG. 12 also illustrates the upper low voltage compartment 107, the exhaust chamber 112, and the plenum chamber 105 as disclosed in the detailed description of FIG. 1. When an electrical component, for example, the control power transformer 119, is mounted in the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101, the middle compartment 102 b and the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101 are separated by a barrier 101 d. When an electrical component, for example, the epoxy encapsulated potential transformer 120, is mounted in the lower compartment 102 c defined in the second section 101 b of the electrical enclosure 101, the lower compartment 102 c and the rear compartment 102 e defined in the second section 101 b of the electrical enclosure 101 are separated by a barrier 101 e.

In an embodiment, the front accessible switchgear assembly 100 disclosed herein further comprises one or more fuse sleeve assemblies 120 a operably connected to the epoxy encapsulated potential transformer 120 as disclosed in the detailed description of FIGS. 23A-23E. If the epoxy encapsulated potential transformer 120 is mounted in the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101 and if there is an arcing event in the middle compartment 102 b, the gases are directed to the exhaust chamber 112 via the flap 106 b exemplarily illustrated in FIG. 1A, into the plenum chamber 105. The fuse sleeve assemblies 120 a operably connected to the epoxy encapsulated potential transformer 120 contact the cylindrical bus 104 c that runs inside the mounting block assembly 104, as exemplarily illustrated in FIG. 23E, within the electrical enclosure 101, thereby creating an ultra compact front accessible switchgear assembly 100.

In an embodiment, the front accessible switchgear assembly 100 disclosed herein further comprises one or more fuse sleeve assemblies 119 a operably connected to the control power transformer 119 as disclosed in the detailed description of FIGS. 22A-22E. The fuse sleeve assemblies 119 a operably connected to the control power transformer 119 contact, for example, the cylindrical bus 104 c that runs inside the mounting block assembly 104, as exemplarily illustrated in FIG. 22E, within the electrical enclosure 101, thereby creating an ultra compact front accessible switchgear assembly 100. The fuse sleeve assemblies 119 a and 120 a of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively contact one or more of the bus bars 103, for example, in a rear compartment 102 e within the electrical enclosure 101 via the mounting block assembly 104. The configuration and functioning of the fuse sleeve assemblies 119 a and 120 a of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively in the front accessible switchgear assembly 100 also apply to the multi-access switchgear assembly 1700 exemplarily illustrated in FIG. 17, FIG. 18A, and FIG. 19A.

FIG. 13 exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly 100, showing the electrical cables 111 electrically connected to the upper horizontal bus bars 103 a via the cable connection bus bars 103 c. The upper low voltage compartment 107 is isolated from the plenum chamber 105 via the exhaust chamber 112. The exhaust chamber 112 isolates the gases from the plenum chamber 105 from entering the upper low voltage compartment 107, for example, by using a sheet metal barrier. In the front accessible switchgear assembly 100 exemplarily illustrated in FIG. 13, the middle compartment 102 b can accommodate the control power transformer 119 or the epoxy encapsulated potential transformer 120. The middle compartment 102 b can also be configured as a low voltage compartment 107.

FIGS. 14A-14B exemplarily illustrate cut-away left orthogonal views of a second section 101 b of the front accessible switchgear assembly 100, showing electrical connection of the upper horizontal bus bars 103 a from a first section 101 a of the electrical enclosure 101 to the lower horizontal bus bars 103 d in the second section 101 b of the electrical enclosure 101 via the transitional bus bars 103 b.

The upper horizontal bus bars 103 a and the lower horizontal bus bars 103 d can be configured to connect adjacent sections 101 a and 101 b of a single front accessible switchgear assembly 100 and/or adjacent switchgear assemblies. In an embodiment, the upper horizontal bus bars 103 a are electrically connected to the lower horizontal bus bars 103 d via, for example, the circuit breaker 118 as exemplarily illustrated in FIG. 15. In an embodiment, the upper horizontal bus bars 103 a run between the first section 101 a and the second section 101 b of the electrical enclosure 101 of the front accessible switchgear assembly 100 to electrically connect the upper horizontal bus bars 103 a to the output of the circuit breaker 118. In another embodiment, the upper horizontal bus bars 103 a are configured to electrically connect to the electrical cables 111 in the lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101. The front accessible switchgear assembly 100 disclosed herein allows flexibility in configuring the bus bars 103 for any electrical connections required in the electrical enclosure 101.

Also illustrated in FIG. 14B is the control power transformer 119 electrically connected in the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101, and the epoxy encapsulated potential transformer 120 electrically connected in the lower compartment 102 c defined in the second section 101 b of the electrical enclosure 101. The internal fuse clips 119 b and 120 b of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively exemplarily illustrated in FIG. 14B, are disclosed in the detailed description of FIGS. 22A-22E and FIGS. 23A-23E respectively.

FIG. 15 exemplarily illustrates a cut-away left orthogonal view of the first section 101 a of the front accessible switchgear assembly 100, showing the upper horizontal bus bars 103 a accommodated in a central compartment 102 d defined in the first section 101 a of the front accessible switchgear assembly 100 and electrically connected to the lower horizontal bus bars 103 d that extend into the second section 101 b of the front accessible switchgear assembly 100, via mounting block assemblies 104 with a mounted circuit breaker 118. In this embodiment, the upper horizontal bus bars 103 a are connected to the lower horizontal bus bars 103 d in the rear compartment 102 e of the electrical enclosure 101 via the mounting block assemblies 104 with the mounted circuit breaker 118. The circuit breaker 118 is electrically connected in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101. The tulip contacts 118 f on the arms 118 c of the circuit breaker 118 contact the cylindrical bus 104 c that runs inside each of the mounting block assemblies 104, as exemplarily illustrated in FIG. 21D, which extend into the central compartment 102 d and the rear compartment 102 e defined in the first section 101 a of the electrical enclosure 101 as exemplarily illustrated in FIG. 15.

FIG. 16A exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly 100, showing an upper compartment 102 a of the front accessible switchgear assembly 100 configured for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101, where the electrical cables 111 are electrically connected to the upper horizontal bus bars 103 a via the cable connection bus bars 103 c. In this embodiment, the front accessible switchgear assembly 100 further comprises cable entry and exit windows 122 defined on the upper end 101 f of the electrical enclosure 101. The electrical cables 111 enter the front upper compartment 102 a defined in the electrical enclosure 101 via the cable entry and exit windows 122. In this embodiment, the front upper compartment 102 a is a full section extending from the upper end 101 f of the electrical enclosure 101 towards the front lower compartment 102 c in the electrical enclosure 101. When the electrical cables 111 extend into the upper compartment 102 a from the upper end 101 f of the electrical enclosure 101 via the cable entry and exit windows 122, the front upper compartment 102 a and the middle compartment 102 b defined in the electrical enclosure 101 are essentially a single compartment with no sheet metal barriers. In this embodiment, the electrical cables 111 extend into the front upper compartment 102 a and electrically connect to the upper horizontal bus bars 103 a in the rear compartment 102 e defined in the electrical enclosure 101 via the cable connection bus bars 103 c. In an embodiment, the electrical cables 111 are directly connected to the upper horizontal bus bars 103 a. The compartments, for example, 102 a, 102 c, etc., that accommodate the electrical cables 111 cannot be configured as a low voltage compartment 107. In the front accessible switchgear assembly 100 exemplarily illustrated in FIG. 16A, the lower compartment 102 c can accommodate the epoxy encapsulated potential transformer 120. The lower compartment 102 c can also be configured as a low voltage compartment 107.

FIG. 16B exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly 100, showing an upper compartment 102 a of the front accessible switchgear assembly 100 configured for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101. FIG. 16B also illustrates a support bracket 121 that protects an infrared window 108 positioned on the front side 100 a of the front accessible switchgear assembly 100. In an embodiment, a support bracket 121 is also provided for protecting an infrared window 108 positioned on the rear side 100 b of the front accessible switchgear assembly 100 as exemplarily illustrated in FIG. 4B. The support bracket 121 is connected below the infrared window 108 for protecting the infrared window 108 from rupture due to the pressure of gases during an event of arcing. In the event of arcing in the lower compartment 102 c, gases exit through the flap 106 c through the exhaust chamber 112 via the flap 106 b, and into the plenum chamber 105 as exemplarily illustrated in FIG. 1A.

FIG. 16C exemplarily illustrates a cut-away left orthogonal view of the front accessible switchgear assembly 100, showing an upper compartment 102 a of the front accessible switchgear assembly 100 configured for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101. The electrical cables 111 are electrically connected to the lower horizontal bus bars 103 d via the cable connection bus bars 103 c.

FIG. 16D exemplarily illustrates a cut-away left perspective view of the front accessible switchgear assembly 100, showing an upper compartment 102 a of the front accessible switchgear assembly 100 configured for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101. FIG. 16D also illustrates a support bracket 121 that protects an infrared window 108 positioned on the front side 100 a of the front accessible switchgear assembly 100. The support bracket 121 below the infrared window 108 protects the infrared window 108 from rupture due to the pressure of gases during an event of arcing. In the event of arcing in the lower compartment 102 c, gases exit through the flap 106 c through the exhaust chamber 112 via the flap 106 b, and into the plenum chamber 105 as exemplarily illustrated in FIG. 1A.

FIG. 17 exemplarily illustrates a cut-away left perspective view of a multi-access switchgear assembly 1700, showing electrical cables 111 accommodated in a rear lower compartment 102 e, a circuit breaker 118 accommodated in a middle compartment 102 b, and an epoxy encapsulated potential transformer 120 accommodated in a front lower compartment 102 c, in a single section 101 a of the multi-access switchgear assembly 1700. The multi-access switchgear assembly 1700 disclosed herein comprises a compact and arc resistant electrical enclosure 101, multiple compartments 102 defined within the electrical enclosure 101, one or more mounting block assemblies 104, a plenum chamber 105, electrical cables 111, electrical components 113, 118, 119, 120, etc., as exemplarily illustrated in FIG. 17 and FIG. 18A, and bus bars 103, for example, 103 a, 103 b, 103 c, etc. The compartments 102 are configured to interchangeably accommodate one or more electrical components 113, 118, 119, 120, etc., the electrical cables 111, and the bus bars 103. The configuration and functioning of the compartments 102, the low voltage compartment 107, the electrical components 113, 118, 119, 120, etc., the plenum chamber 105, the flaps 106 a, 106 b, 106 c, etc., and the bus bars 103 of the multi-access switchgear assembly 1700 are the same as that disclosed for the front accessible switchgear assembly 100 in the detailed description of FIGS. 1A-16D.

The multi-access switchgear assembly 1700 disclosed herein is a metal clad switchgear assembly. Adjacent sections 101 a and 101 b defined in the electrical enclosure 101 of the multi-access metal clad switchgear assembly 1700 are separated by vertical metal barriers 101 c for compartmentalizing active electrical components 118, 119, 120, etc., in the electrical enclosure 101. The multi-access metal clad switchgear assembly 1700 has a higher duty cycle and a greater number of load operations, for example, about 10 times to about 1000 times greater number of load operations than that of a metal enclosed switchgear assembly. The “multi-access metal clad switchgear assembly” is herein referred to as a “multi-access switchgear assembly”.

The multi-access switchgear assembly 1700 disclosed herein refers to a 15000 volts (V) switchgear assembly and can be extended to higher and lower voltages. The multi-access switchgear assembly 1700 disclosed herein accommodates 15 kilovolt (kV) class equipment and provides solutions for 95 kV lightning impulse voltage and 1200 ampere (A) rating with a control power transformer 119 as exemplarily illustrated in FIG. 18A, rated up to 15 kVA. The multi-access switchgear assembly 1700 disclosed herein can be extended to higher ratings and can be used for low voltage switchgear assemblies rated 600V and below.

The multi-access switchgear assembly 1700 is compact and is configured with a depth of, for example, about 72 inches for front and rear accessibility. The width and height of each of the sections 101 a and 101 b of the electrical enclosure 101 of the multi-access switchgear assembly 1700 are, for example, about 23.62 inches and about 96 inches respectively. The multi-access switchgear assembly 1700 requires a minimum clearance of, for example, about 60 inches from a wall for providing rear access to the multi-access switchgear assembly 1700, with reduced width requirements. Working clearance of about 5 feet or more is provided in the front and the rear of the multi-access switchgear assembly 1700. The multi-access switchgear assembly 1700 is configured to line up with a switchgear having a current rating of about 2000 amperes, thereby enabling usage of circuit breakers 118 having current ratings of about 1200 amperes and 2000 amperes.

The plenum chamber 105 is in communication with one or more of the compartments 102 and in adjacent communication with the exhaust chamber 112. The plenum chamber 105 provides an exit path for releasing pressure and gases generated by one or more of the electrical components 113, 118, 119, 120, etc., and the electrical cables 111 accommodated in the compartments 102 during an event of arcing within the electrical enclosure 101. The multi-access switchgear assembly 1700 disclosed herein can accommodate a plenum chamber 105 with more depth and volume compared to the front accessible switchgear assembly 100 exemplarily illustrated in FIGS. 1A-16D, due to which the pressure within the various compartments 102 of the multi-access switchgear assembly 1700 during an arcing event within the electrical enclosure 101 is lower compared to that of the front accessible switchgear assembly 100. The compartments 102 of the multi-access switchgear assembly 1700 are configured to minimize the pressure of gases during an arcing event. Moreover, the volume of the lower compartments 102 c is larger in the multi-access switchgear assembly 1700 and therefore there is less pressure build up during an arcing event.

One or more of the compartments 102 defined within the electrical enclosure 101 of the multi-access switchgear assembly 1700 is configured for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101 for allowing front access and/or rear access to the electrical cables 111. For example, a front lower compartment 102 c and/or a rear lower compartment 102 e are configured for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101 for allowing front access and/or rear access to the electrical cables 111 respectively. As exemplarily illustrated in FIG. 17, the multi-access switchgear assembly 1700 allows rear access to the electrical cables 111 accommodated in the rear lower compartment 102 e of the multi-access switchgear assembly 1700.

In the multi-access switchgear assembly 1700 exemplarily illustrated in FIG. 17, the front lower compartment 102 c accommodates the epoxy encapsulated potential transformer 120, while the middle compartment 102 b accommodates the circuit breaker 118. The circuit breaker 118 contacts one or more of the bus bars 103 via the mounting block assembly 104. In this embodiment, the epoxy encapsulated potential transformer 120 is accommodated in the front lower compartment 102 c of the multi-access switchgear assembly 1700, while the electrical cables 111 are accommodated in the rear lower compartment 102 e of the multi-access switchgear assembly 1700. The epoxy encapsulated potential transformer 120, the electrical cables 111, and the circuit breaker 118 are therefore positioned in a single section 101 a of the multi-access switchgear assembly 1700, thereby minimizing the need for additional sections in the multi-access switchgear assembly 1700. The multi-access switchgear assembly 1700, exemplarily illustrated in FIG. 17, provides front access to the circuit breaker 118 and the epoxy encapsulated potential transformer 120.

In an embodiment, where the epoxy encapsulated potential transformer 120 is mounted in the front lower compartment 102 c, and the electrical cables 111 are mounted in the rear lower compartment 102 e defined in the first section 101 a of the electrical enclosure 101 of the multi-access switchgear assembly 1700, the front lower compartment 102 c and the rear lower compartment 102 e defined in the electrical enclosure 101 are separated by barriers 101 e as exemplarily illustrated in FIG. 17.

The multi-access switchgear assembly 1700 exemplarily illustrated in FIG. 17 further comprises one or more inspection windows 109 positioned at predetermined locations on one or more of a front side 1700 a and a rear side 1700 b of the multi-access switchgear assembly 1700. The inspection windows 109, for example, windows made of Lexan® of Saudi Basic Industries Corp, provide a front visual indication and/or a rear visual indication of the electrical components 113, 118, 119, 120, etc., the electrical cables 111, and the bus bars 103 in the compartments 102 for signs of heating of the electrical components 113, 118, 119, 120, etc., the electrical cables 111, and the bus bars 103 or any other abnormal conditions. The multi-access switchgear assembly 1700 further comprises one or more infrared windows 108 positioned at predetermined locations on one or more of a front side 1700 a and a rear side 1700 b of the multi-access switchgear assembly 1700 for front scanning and/or rear scanning of the electrical components 113, 118, 119, 120, etc., the electrical cables 111, and the bus bars 103 in the compartments 102 for inspection and maintenance. The bus bars 103 are electrically connected, for example, in the rear compartments 102 e of the multi-access switchgear assembly 1700. The multi-access switchgear assembly 1700 disclosed herein allows flexibility in configuring the bus bars 103 for any electrical connections required in the electrical enclosure 101.

In an embodiment, the multi-access switchgear assembly 1700 further comprises surge arresters 116 not shown in FIG. 17. The surge arresters 116 are positioned, for example, in the rear compartments 102 e defined in the electrical enclosure 101 for protecting the electrical components 113, 118, 119, 120, etc., the bus bars 103, the inspection windows 109, the infrared windows 108, the electrical cables 111, the mounting block assembly 104, the compartments 102 defined within the electrical enclosure 101, etc., in an event of a lightning surge. The surge arresters 116 are electrically connected to one or more of the bus bars 103 in the electrical enclosure 101 via short high voltage electrical cables 110.

FIG. 17 also illustrates insulating boots 123 for the mounting block assembly 104. The insulating boots 123 are flexible boot like covers that enclose exposed bus bars 103 in the multi-access switchgear assembly 1700. The insulating boots 123 provide additional insulation which increases creepage distance and helps in withstanding lightning impulses over time as insulators degrade. The insulating boots 123 therefore help maintain long-term reliability of the multi-access switchgear assembly 1700. The insulating boots 123 are custom designed for each multi-access switchgear assembly 1700 and tightly fit to enclose the exposed bus bars 103, thereby ensuring proper insulation. Moreover, the insulating boots 123 leave no part of live or active bus bars 103 carrying electric current exposed, thereby ensuring that no accidental contact occurs with the live bus bars 103 when the doors 115, as exemplarily illustrated in FIGS. 1A-1B, FIG. 6, etc., provided for accessing the compartments 102 defined in the first section 101 a and the second section 101 b of the electrical enclosure 101 are opened for maintenance.

In the multi-access switchgear assembly 1700 exemplarily illustrated in FIG. 17, the insulating boots 123 cover an exposed bus attached to the cylindrical bus 104 c that runs inside each of the mounting legs 104 a of the mounting block assembly 104 exemplarily illustrated in FIG. 20A and FIG. 20C. Custom insulating boots (not shown) also cover exposed ends of the upper horizontal bus bars 103 a. Moreover, other custom insulating boots (not shown) cover the exposed bus bars 103 that connect the electrical cables 111, the epoxy encapsulated potential transformer 120, the control power transformer 119, and the surge arresters 116 within the electrical enclosure 101.

As exemplarily illustrated in FIG. 17, the multi-access switchgear assembly 1700 comprises two mounting block assemblies 104 for accommodating incoming circuit breaker connections 118 e and outgoing circuit breaker connections 118 d. The current transformers 113 are mounted on both the mounting block assemblies 104 that accommodate the incoming circuit breaker connections 118 e and the outgoing circuit breaker connections 118 d.

FIG. 18A exemplarily illustrates a cut-away left perspective view of the multi-access switchgear assembly 1700, showing electrical cables 111 accommodated in the rear lower compartment 102 e of the multi-access switchgear assembly 1700 and electrically connected to the upper horizontal bus bars 103 a via the cable connection bus bars 103 c. In the multi-access switchgear assembly 1700 exemplarily illustrated in FIG. 18A, the middle compartment 102 b accommodates the control power transformer 119, the front lower compartment 102 c accommodates the epoxy encapsulated potential transformer 120, and the rear lower compartment 102 e accommodates the electrical cables 111. The multi-access switchgear assembly 1700, exemplarily illustrated in FIG. 18A, provides front access to the control power transformer 119 and the epoxy encapsulated potential transformer 120. In this embodiment, the upper compartment 102 a can be configured as the low voltage compartment 107 for accommodating control equipment. The low voltage compartment 107 is isolated from the plenum chamber 105 and other compartments 102 b, 102 c, etc. The configuration and functioning of the low voltage compartment 107 is disclosed in the detailed description of FIGS. 1A-1B.

Moreover, the electrical cables 111 are connected to the upper horizontal bus bars 103 a via the cable connection bus bars 103 c. In an embodiment, the electrical cables 111 are directly connected to the upper horizontal bus bars 103 a. As exemplarily illustrated in FIG. 18A, the multi-access switchgear assembly 1700 allows rear access to the electrical cables 111 accommodated in the rear lower compartment 102 e of the multi-access switchgear assembly 1700. The epoxy encapsulated potential transformer 120, the electrical cables 111, and the control power transformer 119 are positioned in a single section 101 a of the multi-access switchgear assembly 1700, thereby minimizing the need for additional sections in the multi-access switchgear assembly 1700.

In an embodiment, one or more of the horizontal bus bars, for example, 103 a electrically connected, for example, in the rear compartments 102 e within the electrical enclosure 101 allow connection to adjacent sections 101 a and 101 b defined in the electrical enclosure 101, connection between the electrical components 118, 119, 120, etc., in the adjacent sections 101 a and 101 b defined in the electrical enclosure 101, connection between the electrical cables 111 in adjacent compartments 102 in the electrical enclosure 101 as exemplarily illustrated in FIG. 19A, and in the adjacent sections 101 a and 101 b defined in the electrical enclosure 101, and connection to one or more other switchgear assemblies. The multi-access switchgear assembly 1700 can be configured to line up with a switchgear having a current rating of, for example, about 2000 amperes using the horizontal bus bars 103 a rated 2000 amperes, thereby enabling usage of the circuit breakers 118 having current ratings of, for example, about 1200 amperes and 2000 amperes in a single line up.

FIG. 18B exemplarily illustrates a bottom orthogonal view of the multi-access switchgear assembly 1700 of FIG. 18A, showing the electrical cables 111 entering into the electrical enclosure 101 via the rear lower compartment 102 e of the multi-access switchgear assembly 1700. The bottom of the rear lower compartment 102 e defined in the electrical enclosure 101 comprises cable entry and exit windows 122 that allow the electrical cables 111 to enter into and/or exit out from the rear lower compartment 102 e of the multi-access switchgear assembly 1700. The lower horizontal bus bars 103 d extending outwardly from the multi-access switchgear assembly 1700, for example, allow connection to one or more other switchgear assemblies.

FIG. 19A exemplarily illustrates a cut-away left perspective view of the multi-access switchgear assembly 1700, showing electrical cables 111 accommodated in the front lower compartment 102 c and the rear lower compartment 102 e of the multi-access switchgear assembly 1700. FIG. 19A also illustrates cable connection bus bars 103 c that connect the electrical cables 111 in the front lower compartment 102 c and the rear lower compartment 102 e of the multi-access switchgear assembly 1700 to the upper horizontal bus bars 103 a. In this embodiment, the multi-access switchgear assembly 1700 allows front access and rear access to the electrical cables 111 accommodated in the front lower compartment 102 c and the rear lower compartment 102 e of the multi-access switchgear assembly 1700 respectively. Furthermore, in this embodiment, the upper compartment 102 a is configured as the low voltage compartment 107 and the middle compartment 102 b accommodates the circuit breaker 118. The multi-access switchgear assembly 1700, exemplarily illustrated in FIG. 19A, provides front access to the circuit breaker 118.

FIG. 19B exemplarily illustrates a bottom orthogonal view of the multi-access switchgear assembly 1700 of FIG. 19A, showing the electrical cables 111 entering into the electrical enclosure 101 via the front lower compartment 102 c and the rear lower compartment 102 e of the multi-access switchgear assembly 1700. The bottom of the front lower compartment 102 c and the rear lower compartment 102 e defined in the electrical enclosure 101 comprises cable entry and exit windows 122 that allow the electrical cables 111 to enter into and/or exit out from the front lower compartment 102 c and the rear lower compartment 102 e of the multi-access switchgear assembly 1700 respectively.

FIGS. 20A-20C exemplarily illustrate perspective views of a mounting block assembly 104 for the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. The mounting block assembly 104 for the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 is configured as a monoblock for mounting the electrical components 113, 118, 119, 120, etc., in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. As used herein, the term “monoblock” refers to a block configuration that accommodates all three phases in the electrical enclosure 101. The monoblock configuration of the mounting block assembly 104 allows compact arrangement of the electrical components 113, 118, 119, 120, etc., in the electrical enclosure 101, thereby providing a compact front accessible switchgear assembly 100 and a compact multi-access switchgear assembly 1700. The monoblock configuration requires a large compression mold and is configured to meet Underwriters Laboratories (UL) flame and tracking tests for a 15 kV front accessible switchgear assembly 100 and a 15 kV multi-access switchgear assembly 1700.

The mounting block assembly 104 comprises a base mounting block 104 b, mounting legs 104 a, and a mounting block cover 104 d. The mounting block assembly 104 is positioned in one or more of the compartments 102 defined in the first section 101 a and the second section 101 b of the electrical enclosure 101, as exemplarily illustrated in FIGS. 1A-1B, FIGS. 2-5, FIG. 11A, FIG. 12, FIG. 15, FIG. 17, FIG. 18A, and FIG. 19A, for mounting one or more of the electrical components, for example, one or more current transformers 113 having one of multiple current ratios. The current transformers 113 are used for metering or relaying in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. Each current transformer 113 mounted on a mounting leg 104 a of one mounting block assembly 104 has the same current ratio, for example, 1200:5. The current transformers 113 mounted on a mounting leg 104 a of another mounting block assembly 104 in another section 101 a or 101 b of the electrical enclosure 101 may have a different current ratio, for example, 600:5 or 300:5. Therefore, in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700, a mounting block assembly 104 in one of the compartments 102 mounts current transformers 113 having a current ratio of 1200:5, while another mounting block assembly 104 in another one of the compartments 102 mounts current transformers 113 having a current ratio of 600:5 or 300:5.

The mounting legs 104 a extend frontwardly from the base mounting block 104 b, as exemplarily illustrated in FIG. 20A, for mounting the electrical components 113, 118, 119, 120, etc., and for allowing front access to the mounted electrical components 113, 118, 119, 120, etc., for inspection and maintenance. A cylindrical bus 104 c, for example, made of copper runs inside each of the mounting legs 104 a of the mounting block assembly 104. The cylindrical bus 104 c is configured, for example, as a copper pin. The cylindrical bus 104 c extends frontwardly to contact the electrical components, for example, the circuit breaker 118 mounted in the mounting block assembly 104. For example, the cylindrical bus 104 c of the mounting block assembly 104 contacts each of the tulip contacts 118 f of the circuit breaker 118 when the circuit breaker 118 is racked in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101 as exemplarily illustrated in FIGS. 21C-21D.

In another example, the cylindrical bus 104 c of the mounting block assembly 104 contacts each of the fuse sleeve assemblies 119 a of the control power transformer 119, when the control power transformer 119 is racked in the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101 as exemplarily illustrated in FIGS. 22D-22E. In another example, the cylindrical bus 104 c of the mounting block assembly 104 contacts each of the fuse sleeve assemblies 120 a of the epoxy encapsulated potential transformer 120, when the epoxy encapsulated potential transformer 120 is racked in the lower compartment 102 c defined in the second section 101 b of the electrical enclosure 101 as exemplarily illustrated in FIGS. 23D-23E.

The mounting block cover 104 d as exemplarily illustrated in FIG. 20B is removably attached to the base mounting block 104 b for enclosing, for example, the mounted current transformers 113 on the mounting legs 104 a as exemplarily illustrated in FIG. 20C. Brackets 104 e are provided on both sides of the mounting block assembly 104 for enclosing the mounting block cover 104 d and the mounted current transformers 113 on the mounting legs 104 a and for providing support to the mounting block assembly 104. The mounting block cover 104 d is removable for providing front access to the mounted current transformers 113 for inspection, maintenance, and service. For example, the mounting block cover 104 d can be removed from the front by operating personnel for inspecting the current transformers 113 mounted on the mounting block assembly 104.

The mounting block assembly 104 with a pair of current transformers 113 mounted on each of the mounting legs 104 a on the base mounting block 104 b, where the pair of the current transformers 113 is enclosed by the mounting block cover 104 d and the brackets 104 e is exemplarily illustrated in FIG. 20C. The current transformer 113 is, for example, a ring type current transformer with a voltage rating of, for example, about 600V. The compact design of the mounting block assembly 104 allows usage of current transformers 113 of lower voltage rating, for example, about 600V, in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 of a medium voltage, for example, about 15,000V. Each mounting block assembly 104 has rear bus connections. The cylindrical bus 104 c made of, for example, copper, runs inside the mounting legs 104 a of the mounting block assembly 104. When the circuit breaker 118 is mounted in the mounting block assembly 104 in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101, the tulip contacts 118 f on the arms 118 c of the circuit breaker 118 make a solid electrical connection with the cylindrical bus 104 c inside the mounting block assembly 104 as exemplarily illustrated in FIGS. 21C-21D. The cylindrical bus 104 c is in electrical communication with each of the tulip contacts 118 f of the circuit breaker 118 inside the mounting block assembly 104.

The mounting block assembly 104 is configured to reduce temperature rise in the compartments 102. For example, the material of the mounting block assembly 104 is pigmented with a black colored material to limit the temperature rise in the middle compartment 102 b that accommodates the circuit breaker 118 to meet standards of Underwriters Laboratories® and other agency standards. The black colored material of the mounting block assembly 104 keeps the temperature rise in the compartments 102 to allowable agency limits. The mounting block assembly 104 pigmented with the black colored material acts as a black body and absorbs heat, thereby limiting the temperature rise of the electrical cables 111, the electrical components 118, etc., for example, conductors of the circuit breaker 118, and the bus bars 103. The use of black colored material eliminates the need for expensive and bulky heat sinks required to limit the temperature rise of the electrical cables 111, the electrical components 118, etc., and the bus bars 103. The use of the black colored material for the mounting block assemblies 104, painting inside the compartments 102 in black color, and use of larger cross section bus bars 103 in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein achieves a compact footprint.

The mounting block assembly 104 is, for example, made of a glass polyester composition, plastics such as a polyethylene material, or any other suitable material. Glass polyester requires a compression mold, while the polyethylene material uses a silicon mold for quick production of the mounting block assembly 104. Other insulating materials and other molding techniques can be employed for the manufacture of the mounting block assembly 104.

The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 are configured to mount one or more low voltage current transformers 113, for example, 600 volts current transformers in a high voltage circuit, for example, 15000 volts circuit. Mounting of the low voltage current transformers 113, for example, a 600V current transformers in high voltage and medium voltage circuits provides for space and cost savings. The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein enable mounting of multiple current transformers 113 on each phase input and output. More than one current transformer 113 can be installed on each mounting leg 104 a of the mounting block assembly 104. The current transformers 113 are configured, for example, for control, for protection, etc. Furthermore, the current transformers 113 can be installed both on the input side and the output side of the circuit breaker 118 via the mounting block assembly 104. In an embodiment, multiple mounting legs 104 a may be provided for mounting a number of current transformers 113 on the mounting block assembly 104 based on the requirements of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. In another embodiment, the mounting legs 104 a can be elongated to accommodate multiple current transformers 113. Therefore, each mounting block assembly 104 can accommodate multiple current transformers 113. The current transformers 113 are, for example, metering type current transformers, and protection type current transformers, for example, relay class current transformers, etc. The current transformers 113 are adapted for saving space in the electrical enclosure 101.

The current transformers 113 are, for example, ring type toroidal transformers that are mounted on the mounting block assembly 104. The cylindrical bus 104 c that runs inside the mounting legs 104 a of the mounting block assembly 104 passes through each of the windows of the ring type current transformers 113. The current transformer 113 comprises primary turns and secondary turns. The turn ratio of the primary turns to the secondary turns varies in accordance with the electrical rating of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. The electrical rating of the secondary turns of the current transformer 113 is, for example, about 5 A. In an embodiment, the electrical rating of the secondary turns of the current transformer 113 is, for example, about 1 A. In an embodiment, the turn ratio of the primary turns to the secondary turns is, for example, 1200:5. That is, the ratio of the primary turns to the secondary turns can be interpreted as 1200 A to 5 A on a 1200:5 current transformer 113 comprising 1200 primary turns and 5 secondary turns. Current transformers 113 of turn ratios, for example, 2000:5, 600:5, 300:5, etc., may also be utilized in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein. In an embodiment, the primary turns in the current transformer 113 are, for example, electromagnetically coupled to the cylindrical bus 104 c, for example, by induction. The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 can therefore be configured for current transformers 113 with lower electrical rating, for example, about 600V, in a medium voltage circuit with a rating of, for example, about 15,000V.

The mounting block assembly 104 provides sufficient creepage distance such that low voltage current transformers 113 are not exposed to higher voltages. Higher voltage current transformers are bulky and expensive. Using higher voltage current transformers in a small enclosure gives rise to space constrictions and heating of the other electrical components, for example, 118, 119, 120, etc., of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 due to the high voltages present on the higher voltage current transformers. Hence, the design of the base mounting block 104 b, the mounting legs 104 a, and the mounting block cover 104 d provides the creepage required for 95000V so that the low voltage current transformers 113 are protected and hence the low voltage current transformers 113, for example, 600V current transformers can be used to optimize space and save cost. Furthermore, the low voltage current transformers 113 are lightweight, easier to install and replace, and are less costly compared to the higher voltage current transformers. The low voltage current transformers 113 are mounted, for example, with plastic screws to the mounting block assembly 104 as exemplarily illustrated in FIG. 20C. In an embodiment, high voltage current transformers may also be mounted in a compact front accessible switchgear assembly 100 and a compact multi-access switchgear assembly 1700.

In the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein, low voltage current transformers 113, for example, 600V can be used for medium voltage applications at, for example, 15000V. This results in substantial savings and makes a compact design of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 possible. More than one current transformer 113 can be installed on each mounting leg 104 a of the mounting block assembly 104. For example, one metering current transformer and one protection current transformer are mounted on each mounting leg 104 a of the mounting block assembly 104 for a three phase front accessible switchgear assembly 100 or a three phase multi-access switchgear assembly 1700.

FIGS. 21A-21B exemplarily illustrate perspective views of a circuit breaker 118 utilized in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700, showing tulip contacts 118 f of the circuit breaker 118. The circuit breaker 118 is electrically connected in, for example, the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101 as exemplarily illustrated in FIG. 1B, FIG. 4A, FIG. 11A, FIG. 15, FIG. 17, and FIG. 19A. The circuit breaker 118 is an automatically operated electrical switch designed to protect the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 from damage caused by an overload or a short circuit. The circuit breaker 118 detects a fault condition in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 and immediately discontinues electrical flow by interrupting continuity. In an embodiment, one or more current transformers 113 are electrically connected on an input side of the circuit breaker 118 and an output side of the circuit breaker 118.

A cord 118 a configured as, for example, an umbilical cord, is electrically connected to the circuit breaker 118 for low voltage connection within the electrical enclosure 101. The cord 118 a makes the low voltage connection via a connector 118 b, for example, a male connector as exemplarily illustrated in FIGS. 21A-21B. The connector 118 b is disposed in, for example, the middle compartment 102 b just above the circuit breaker 118. There is a positive connection when the circuit breaker 118 is in a connected or racked-in position, or in a withdrawn or racked-out position. The use of the connector 118 b eliminates the need for an additional test position to check the low voltage connection. The circuit breaker 118 is mounted on a truck 118 g with rollers 118 h that roll on a track (not shown) positioned in the middle compartment 102 b, for racking the circuit breaker 118 in and out of the middle compartment 102 b. A racking tool (not shown) may be inserted into a circular opening 118 j provided on the truck 118 g of the circuit breaker 118 for racking the circuit breaker 118 in and out of the middle compartment 102 b. The handles 118 i on the truck 118 g of the circuit breaker 118 are used to remove the circuit breaker 118 from the track (not shown) in the middle compartment 102 b. The circuit breaker 118 comprises the tulip contacts 118 f provided on the arms 118 c extending outwardly from the circuit breaker 118. Each of the tulip contacts 118 f of the circuit breaker 118 makes contact with the cylindrical bus 104 c that runs inside each mounting leg 104 a of the mounting block assembly 104, as exemplarily illustrated in FIG. 21D, in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101.

FIG. 21C exemplarily illustrates a plan view showing connection of the circuit breaker 118 within the mounting block assembly 104. As exemplarily illustrated in FIG. 21C, ring type current transformers 113 are mounted on the mounting legs 104 a of the mounting block assembly 104. When the circuit breaker 118 is installed and racked into the middle compartment 102 b, the tulip contacts 118 f on the arms 118 c of the circuit breaker 118 make electrical contact with the cylindrical bus 104 c that runs inside the mounting legs 104 a of the mounting block assembly 104.

FIG. 21D exemplarily illustrates a sectional view taken at section A-A of FIG. 21C, showing connection of a tulip contact 118 f of the circuit breaker 118 to a cylindrical bus 104 c that runs inside the mounting block assembly 104. When the circuit breaker 118 is installed and racked into the middle compartment 102 b, the tulip contact 118 f housed on each arm 118 c of the circuit breaker 118 enters the mounting block cover 104 d and makes solid electrical contact with the cylindrical bus 104 c that runs inside each mounting leg 104 a of the mounting block assembly 104. Low voltage current transformers 113 are also installed on the mounting legs 104 a of the mounting block assembly 104 and are in electrical communication with the cylindrical bus 104 c that runs inside each of the mounting legs 104 a of the mounting block assembly 104. The low voltage current transformers 113 measure current through the cylindrical bus 104 c.

For each circuit breaker 118, there are two mounting block assemblies 104, one for incoming breaker connections 118 e and one for outgoing breaker connections 118 d as exemplarily illustrated in FIG. 11A, FIG. 15, and FIG. 17. The low voltage current transformers 113 can be installed on both the incoming breaker connections 118 e and the outgoing breaker connections 118 d by mounting the low voltage current transformers 113 on the mounting block assemblies 104. In an embodiment, multiple current transformers 113 can be accommodated on each of the mounting block assemblies 104.

FIGS. 22A-22B exemplarily illustrate perspective views of a control power transformer 119 comprising fuse sleeve assemblies 119 a utilized in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. The control power transformer 119 is electrically connected in, for example, the middle compartment 102 b defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, FIG. 14B, and FIG. 18A. The control power transformer 119 is used in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 to provide low voltage control power to the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 and building emergency or auxiliary power.

The fuse sleeve assemblies 119 a successfully pass 95000V lightning impulse tests for a 15000V front accessible switchgear assembly 100 and a 15000V multi-access switchgear assembly 1700 and other voltage switchgear assemblies. The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein further comprise epoxy coated bus bars 103 with a small phase-to-phase distance, for example, 3 inch spacing, between the phases to pass the lightning impulse test. The fuse sleeve assemblies 119 a are mounted on an enclosure 119 c of the control power transformer 119. The enclosure 119 c of the control power transformer 119 is made of a polycarbonate resin thermoplastic material, for example, Lexan® of Saudi Basic Industries Corp. The enclosure 119 c of the control power transformer 119 is attached to a metal barrier 119 g. Each control power transformer 119 has two fuse sleeve assemblies 119 a. The fuse sleeve assemblies 119 a are operably connected to the control power transformer 119 and allow high voltage primary connections of the control power transformer 119 in the electrical enclosure 101, for example, via the mounting block assembly 104. Each of the fuse sleeve assemblies 119 a contacts the cylindrical bus 104 c that runs inside each of the mounting legs 104 a of the mounting block assembly 104. Each of the fuse sleeve assemblies 119 a is attached to the Lexan enclosure 119 c of the control power transformer 119.

Each of the fuse sleeve assemblies 119 a of the control power transformer 119 comprises an internal fuse clip 119 b and a fuse 119 j as exemplarily illustrated in FIG. 22C. The fuse sleeve assemblies 119 a attached to the control power transformer 119 are connected through the rear of the middle compartment 102 b and mounted in the mounting block assembly 104 as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, and FIG. 18A. Fuse connections are made from the fuse sleeve assemblies 119 a of the control power transformer 119 to the cylindrical bus 104 c that runs inside each of the mounting legs 104 a of the mounting block assembly 104 as exemplarily illustrated in FIG. 22E. The mounting block assembly 104 for mounting the control power transformer 119 does not have a mounting block cover 104 d and the current transformer 113 mounting capability as exemplarily illustrated in FIGS. 22D-22E.

The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein are configured to insulate fuses 119 j, as exemplarily illustrated in FIG. 22C, that connect to the control power transformer 119. The insulated fuses 119 j are enclosed in the epoxy fuse sleeve assemblies 119 a that are mounted on the Lexan enclosure 119 c of the control power transformer 119. Each of the fuse sleeve assemblies 119 a is glued to the epoxy at the ends of the Lexan enclosure 119 c. Each of the fuse clips 119 b of the fuse sleeve assemblies 119 a makes contact with the cylindrical bus 104 c inside the mounting block assembly 104 as exemplarily illustrated in FIG. 22E. In this embodiment, the mounting block assembly 104 is a single mounting block assembly 104 since there are no current transformers 113 to be mounted. The other end of each of the fuses 119 j of the fuse sleeve assemblies 119 a has a mating built-in fuse clip and a short cable, which goes through a hole in the Lexan enclosure 119 c to make a connection to a high voltage terminal of the control power transformer 119 at either end. The cylindrical bus 104 c inside the mounting block assembly 104 is machined such that the cylindrical bus 104 c has a concave curvature so that each of the fuse sleeve assemblies 119 a of the control power transformer 119 makes good contact when the control power transformer 119 is racked in during normal operation. The control power transformer 119 is mounted on a truck 119 e with rollers 119 f that roll on a track (not shown) positioned in the middle compartment 102 b defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, FIG. 14B, and FIG. 18A, for racking the control power transformer 119 in and out of the middle compartment 102 b. A racking tool (not shown) may be inserted into a circular opening 119 i provided on the truck 119 e of the control power transformer 119 for racking the control power transformer 119 in and out of the middle compartment 102 b. The handles 119 h on the truck 119 e of the control power transformer 119 are used to remove the control power transformer 119 from the track (not shown) in the middle compartment 102 b.

The control power transformer 119 requires only two phases namely phase A and phase C to power the control power transformer 119. The two phases, namely, phase A and phase C connect to external high voltage bus bars 103 via the fuse clips 119 b. The Lexan enclosure 119 c provides an insulating barrier between the high voltage control power transformer terminals and the chassis of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 that are at ground potential. Each of the fuse sleeve assemblies 119 a provides an insulating barrier between the high voltage fuse connections and the chassis of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. Each of the fuse sleeve assemblies 119 a also encloses the fuse clip 119 b so that energized high voltage components are not exposed. Moreover, the mounting block assembly 104 provides isolation between the phases of the control power transformer 119. Furthermore, the curvature of the cylindrical bus 104 c inside the mounting block assembly 104 keeps each fuse clip 119 b inside each of the fuse sleeve assemblies 119 a to prevent exposure of active or energized components at any time.

The control power transformer 119 comprises low voltage contacts 119 d in the front of the control power transformer 119 as exemplarily illustrated in FIG. 22A, FIG. 22C, and FIG. 22E. The low voltage contacts 119 d are configured to disengage from low voltage connections within the electrical enclosure 101 for preventing an event of arcing. The entire control power transformer 119 is designed such that the low voltage contacts 119 d disengage before disengagement of the high voltage contacts for safety. Moreover, the secondary connections can have either a low voltage breaker mounted on the front or a fuse pull out in the low voltage compartment 107 to safely disconnect the low voltage connections before racking the control power transformer 119 out of the middle compartment 102 b. If the low voltage connection, for example, the control power transformer load, is not disconnected, there is a possibility of creating an arcing event when the control power transformer 119 is racked out since primary connections are at 15000V. Hence, the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein provide additional safety features.

FIG. 22C exemplarily illustrates a perspective view of the control power transformer 119, showing an exploded view of one of the fuse sleeve assemblies 119 a operably connected to the control power transformer 119. Each of the fuse sleeve assemblies 119 a comprises the fuse 119 j and the fuse clip 119 b. The fuse clip 119 b holds the fuse 119 j within the fuse sleeve assemblies 119 a and is in electrical communication with the cylindrical bus 104 c inside the mounting block assembly 104 as exemplarily illustrated in FIG. 22E, when the control power transformer 119 is racked in the middle compartment 102 b during normal operation.

FIG. 22D exemplarily illustrates a plan view showing connection of the control power transformer 119 to the mounting block assembly 104. Each of the fuse sleeve assemblies 119 a comprising the fuse 119 j and the fuse clip 119 b electrically contacts the cylindrical bus 104 c of the mounting block assembly 104 as exemplarily illustrated in FIG. 22E, when the control power transformer 119 is racked into the middle compartment 102 b defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, and FIG. 18A. The mounting block assembly 104 is configured to accommodate each of the fuse sleeve assemblies 119 a and isolate phases of the control power transformer 119.

FIG. 22E exemplarily illustrates a sectional view taken at section B-B of FIG. 22D, showing connection of the control power transformer 119 to a cylindrical bus 104 c that runs inside the mounting block assembly 104. Each of the fuse sleeve assemblies 119 a of the control power transformer 119 encloses the fuse 119 j and the fuse clip 119 b. The control power transformer 119 is mounted on a truck 119 e with rollers 119 f that roll on a track (not shown) positioned in the middle compartment 102 b, for racking the control power transformer 119 in and out of the middle compartment 102 b as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, FIG. 14B, and FIG. 18A. In an embodiment, when the control power transformer 119 is racked in, the fuse clip 119 b of each of the fuse sleeve assemblies 119 a comes in contact with the cylindrical bus 104 c of the mounting block assembly 104. The cylindrical bus 104 c is attached to a copper bracket 104 f in the mounting block assembly 104 via a fastener 104 g such as a bolt. The copper bracket 104 f electrically communicates with one or more of the bus bars 103, for example, the upper horizontal bus bars 103 a via high voltage electrical cables (not shown). The fuse clip 119 b therefore contacts the concave cylindrical bus 104 c of the mounting block assembly 104. The contact between the fuse clip 119 b and the cylindrical bus 104 c provides electrical communication between the control power transformer 119 and the mounting block assembly 104. In an embodiment, the fuse sleeve assemblies 119 a operably connected to the control power transformer 119 contact one or more of the bus bars 103, for example, in the rear compartments 102 e within the electrical enclosure 101 via the mounting block assembly 104.

FIGS. 23A-23B exemplarily illustrate perspective views of an epoxy encapsulated potential transformer 120 utilized in the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700. The epoxy encapsulated potential transformer 120 is an instrument transformer used for metering and protection in high-voltage circuits. The epoxy encapsulated potential transformer 120 is designed to present negligible load to a power supply being measured and to have a precise voltage ratio to accurately step down high voltages so that metering and protective relay equipment can be operated at a lower potential. The potential transformer 120 is a designed and encapsulated in, for example, epoxy. The epoxy encapsulated potential transformer 120 is accommodated and electrically connected in, for example, the middle compartment 102 b, or the front lower compartment 102 c defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 2, FIG. 3, FIG. 5, FIG. 12, FIG. 14B, FIG. 17, and FIG. 18A. The epoxy encapsulated potential transformer 120 may be mounted in the front lower compartment 102 c as exemplarily illustrated in FIG. 2, FIG. 3, FIG. 5, FIG. 12, FIG. 14B, FIG. 17, and FIG. 18A, or in the middle compartment 102 b to provide a low footprint. As exemplarily illustrated in FIG. 2, FIG. 3, FIG. 5, FIG. 12, FIG. 14B, FIG. 17, and FIG. 18A, the epoxy encapsulated potential transformer 120 is electrically connected in the front lower compartment 102 c defined in the electrical enclosure 101. In an embodiment, one or more fuse sleeve assemblies 120 a are electrically connected to the epoxy encapsulated potential transformer 120.

The potential transformer 120 is epoxy encapsulated and enclosed in an enclosure 120 c made of sheet metal since the epoxy provides adequate insulation for a lightning impulse of 95000 volts. The compact epoxy encapsulated potential transformer 120 makes connection to the bus bars 103 via a single mounting block assembly 104 like the control power transformer 119. The mounting block assembly 104 for mounting the epoxy encapsulated potential transformer 120 does not have a mounting block cover 104 d as exemplarily illustrated in FIGS. 23D-23E. The mounting block assembly 104 for each of the control power transformer 119 and the epoxy encapsulated potential transformer 120 is configured to completely accommodate each of the fuse sleeve assemblies 119 a and 120 a of each of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively as exemplarily illustrated in FIG. 22D and FIG. 23D respectively. The control power transformer 119 and the epoxy encapsulated potential transformer 120 are electrically connected in the compartments, for example, the middle compartment 102 b and the front lower compartment 102 c respectively defined in the electrical enclosure 101 via the mounting block assembly 104 as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, FIG. 17, and FIG. 18A. The mounting block assembly 104 for each of the control power transformer 119 and the epoxy encapsulated potential transformer 120 is geometrically the same to ensure that the fuse sleeve assemblies 119 a and 120 a of each of the control power transformer 119 and the epoxy encapsulated potential transformer 120 respectively are captured inside the mounting block assembly 104. The control power transformer 119 has two fuse sleeve assemblies 119 a, for example, phase A and phase C, while the epoxy encapsulated potential transformer 120 has three fuse sleeve assemblies 120 a, for example, phase A, phase B, and phase C. No connection is made in the middle phase B of the control power transformer 119.

Each of the fuse sleeve assemblies 120 a of the epoxy encapsulated potential transformer 120 comprises an internal fuse clip 120 b and a fuse 120 i as exemplarily illustrated in FIG. 23C. The fuse sleeve assemblies 120 a attached to the epoxy encapsulated potential transformer 120 are connected through the rear of the front lower compartment 102 c as exemplarily illustrated in FIG. 12. Fuse connections are made from the fuse sleeve assemblies 120 a of the epoxy encapsulated potential transformer 120 to the cylindrical bus 104 c mounted in the mounting block assembly 104 as exemplarily illustrated in FIG. 23E.

The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein are configured to insulate fuses 120 i that connect to the epoxy encapsulated potential transformer 120. The insulated fuses 120 i, exemplarily illustrated in FIG. 23C, are enclosed in the epoxy fuse sleeve assemblies 120 a that are mounted on the epoxy encapsulated potential transformer 120, which is mounted on the truck 120 d and enclosed by the sheet metal enclosure 120 c. Each of the fuse clips 120 b of the fuse sleeve assemblies 120 a makes contact with the cylindrical bus 104 c that runs inside each of the mounting legs 104 a of the mounting block assembly 104 as exemplarily illustrated in FIG. 23E. In this embodiment, the mounting block assembly 104 is a single mounting block assembly 104 since there are no current transformers 113 to be mounted. The epoxy encapsulated potential transformer 120 is enclosed in, for example, a sheet metal enclosure 120 c, and the fuse sleeve assemblies 120 a are a part of the epoxy encapsulated potential transformer 120. The other end of each of the fuses 120 i of the fuse sleeve assemblies 120 a has a mating built-in fuse clip inside the fuse sleeve assembly 120 a and a short cable internally connected to a high voltage winding of the epoxy encapsulated potential transformer 120 within the epoxy enclosure. The potential transformer 120 is encapsulated in epoxy and the supporting structure of the epoxy encapsulated potential transformer 120 can be made of, for example, a sheet metal.

The above arrangement is for a wye or star connected potential transformer 120 that has three phases and requires three fuse sleeve assemblies 120 a for a wye or star connected supply system with a neutral connection. In an embodiment, two epoxy encapsulated potential transformers 120 may also be employed with three fuse sleeve assemblies 120 a in an open delta configuration for ungrounded delta connected supply systems (not shown) to prevent damage of the epoxy encapsulated potential transformers 120 in the event of a ground fault by the flow of zero sequence currents. In the open delta configuration, two epoxy encapsulated potential transformers 120 are used and a plexi-glass shield is mounted on top of the two epoxy encapsulated potential transformers 120 to mount the three fuse sleeve assemblies 120 a. The fuse sleeve assemblies 120 a are glued to the plexi-glass shield or sheet on top of the two epoxy encapsulated potential transformers 120 on either side, connected to phases A and B and phases B and C of the epoxy encapsulated potential transformers 120. The high voltage common point is connected to the middle B fuse while the other two fuses 120 i are connected to phases A and C.

The cylindrical bus 104 c that runs inside the mounting block assembly 104 is machined such that the cylindrical bus 104 c has a concave curvature so that each of the fuse sleeve assemblies 120 a makes good contact when the epoxy encapsulated potential transformer 120 is racked in during normal operation. The epoxy encapsulated potential transformer 120 is mounted on a truck 120 d that has rollers 120 e which roll on a track (not shown) positioned in the middle compartment 102 b or the lower compartment 102 c defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, FIG. 17, and FIG. 18A, for racking the epoxy encapsulated potential transformer 120 in and out of the middle compartment 102 b or the lower compartment 102 c. A racking tool (not shown) may be inserted into a circular opening 120 h provided on the truck 120 d of the epoxy encapsulated potential transformer 120 for racking the epoxy encapsulated potential transformer 120 in and out of the middle compartment 102 b or the lower compartment 102 c. The handles 120 g on the truck 120 d of the epoxy encapsulated potential transformer 120 are used to remove the epoxy encapsulated potential transformer 120 from the track (not shown) in the middle compartment 102 b or the lower compartment 102 c.

The epoxy encapsulated potential transformer 120 has three connections namely phase A, phase B, and phase C as opposed to the two phases, namely the phase A and the phase C of the control power transformer 119. The epoxy encapsulated potential transformer 120 is designed and tested to withstand a 95000V lightning impulse and has been independently tested to meet Institution of Electrical and Electronics Engineers (IEEE) standards and American National Standards Institute (ANSI) standards for instrument transformers which is much more stringent than the IEC standards. The height of the epoxy encapsulated potential transformer 120 is small making it possible to install the epoxy encapsulated potential transformer 120 in the lower compartment 102 c. When the epoxy encapsulated potential transformer 120 is installed in the lower compartment 102 c, the lower compartment 102 c is separated from the rear compartment 102 e with a barrier 101 e, which makes the lower compartment 102 c small as exemplarily illustrated in FIG. 12. The lower compartment 102 c that accommodates the epoxy encapsulated potential transformer 120 poses challenges to efficiently vent gases in the event of an arcing. The design and venting of the gases of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 are efficient and has been fully tested to IEEE/ANSI standards. The low voltage contacts 120 f of the epoxy encapsulated potential transformer 120 are designed similar to the low voltage contacts 119 d of the control power transformer 119 and have the same advantages and functionalities.

The epoxy encapsulated potential transformer 120 comprises low voltage contacts 120 f in the front of the epoxy encapsulated potential transformer 120. The low voltage contacts 120 f are configured to disengage from low voltage connections within the electrical enclosure 101 for preventing an event of arcing. The entire epoxy encapsulated potential transformer 120 is designed such that the low voltage contacts 120 f disengage before disengagement of the high voltage contacts for safety. Moreover, the secondary connections can have either a low voltage breaker on the sheet metal enclosure 120 c or a fuse pull out in the low voltage compartment 107 to safely disconnect the low voltage connections before racking the epoxy encapsulated potential transformer 120 out of, for example, the lower compartment 102 c. If the low voltage connection, for example, the epoxy encapsulated potential transformer load, is not disconnected, there is a possibility of creating an arcing event when the epoxy encapsulated potential transformer 120 is racked out since primary connections are at 15000V. Hence, the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein provides additional safety features.

The epoxy encapsulated potential transformer load is small and does not typically require a breaker or a fuse pull out to safely disconnect the secondary low voltage loads before the epoxy encapsulated potential transformer 120 is racked out. However, in an embodiment, a secondary breaker or a fuse pull out similar to that of a control power transformer 119 is incorporated in each of the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700.

FIG. 23C exemplarily illustrates a perspective view of the epoxy encapsulated potential transformer 120, showing an exploded view of one of the fuse sleeve assemblies 120 a operably connected to the epoxy encapsulated potential transformer 120. Each of the fuse sleeve assemblies 120 a of the epoxy encapsulated potential transformer 120 comprises the fuse 120 i and the fuse clip 120 b. The fuse clip 120 b holds the fuse 120 i within each of the fuse sleeve assemblies 120 a and is in electrical communication with the cylindrical bus 104 c inside the mounting block assembly 104 as exemplarily illustrated in FIG. 23E, when the epoxy encapsulated potential transformer 120 is racked in the lower compartment 102 c as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, FIG. 14B, FIG. 17, and FIG. 18A. Each of the fuse sleeve assemblies 120 a of the epoxy encapsulated potential transformer 120 allows high voltage primary connections of the epoxy encapsulated potential transformer 120 in the electrical enclosure 101 via the mounting block assembly 104 as exemplarily illustrated in FIG. 12, FIG. 17, and FIG. 18A. Each of the fuse sleeve assemblies 120 a contacts the cylindrical bus 104 c that runs inside each of the mounting legs 104 a of the mounting block assembly 104 as exemplarily illustrated in FIG. 23E.

FIG. 23D exemplarily illustrates a plan view showing connection of the epoxy encapsulated potential transformer 120 to the mounting block assembly 104. Each of the fuse sleeve assemblies 120 a comprising the fuse 120 i and the fuse clip 120 b, as exemplarily illustrated in FIG. 23C, electrically contacts the cylindrical bus 104 c of the mounting block assembly 104 as exemplarily illustrated in FIG. 23E, when the epoxy encapsulated potential transformer 120 is racked into the lower compartment 102 c defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 12, FIG. 17, and FIG. 18A. The mounting block assembly 104 is configured to accommodate each of the fuse sleeve assemblies 120 a and isolate phases of the epoxy encapsulated potential transformer 120.

FIG. 23E exemplarily illustrates a sectional view taken at section C-C of FIG. 23D, showing connection of the epoxy encapsulated potential transformer 120 to a cylindrical bus 104 c that runs inside the mounting block assembly 104. Each of the fuse sleeve assemblies 120 a of the epoxy encapsulated potential transformer 120 encloses the fuse 120 i and the fuse clip 120 b. The epoxy encapsulated potential transformer 120 is mounted on a truck 120 d with rollers 120 e, which facilitates the mounting of the epoxy encapsulated potential transformer 120 on a track (not shown) in the middle compartment 102 b, or the lower compartment 102 c as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, FIG. 14B, FIG. 17, and FIG. 18A. The epoxy encapsulated potential transformer 120 can be racked in and out of the middle compartment 102 b or the lower compartment 102 c. In an embodiment, when the epoxy encapsulated potential transformer 120 is racked in, the fuse clip 120 b of each of the fuse sleeve assemblies 120 a comes in electrical contact with the cylindrical bus 104 c of the mounting block assembly 104. The cylindrical bus 104 c is attached to a copper bracket 104 f in the mounting block assembly 104 via a fastener 104 g such as a bolt. The copper bracket 104 f electrically communicates with one or more of the bus bars 103, for example, the upper horizontal bus bars 103 a via high voltage electrical cables (not shown). The fuse clip 120 b therefore contacts the concave cylindrical bus 104 c of the mounting block assembly 104. The contact between the fuse clip 120 b and the cylindrical bus 104 c provides electrical communication between the epoxy encapsulated potential transformer 120 and the mounting block assembly 104. In an embodiment, the fuse sleeve assemblies 120 a operably connected to the epoxy encapsulated potential transformer 120 contact one or more of the bus bars 103, for example, in the rear compartments 102 e within the electrical enclosure 101 via the mounting block assembly 104.

FIG. 24 illustrates a method for constructing a front accessible switchgear assembly 100. An electrical enclosure 101, for example, with a width of 23.62 inches, a depth of 60 inches, and height of 96 inches is provided 2401. The electrical enclosure 101 comprises multiple compartments 102, for example, upper compartments 102 a, middle compartments 102 b, lower compartments 102 c, a central compartment 102 d, rear compartments 102 e, etc., defined in sections, for example, a first section 101 a and a second section 101 b of the electrical enclosure 101, as exemplarily illustrated in FIGS. 1A-1B and FIGS. 2-16D. The compartments 102 are configured to interchangeably accommodate one or more electrical components, for example, the control equipment, the circuit breaker 118, the control power transformer 119, the epoxy encapsulated potential transformer 120, the electrical cables 111, etc., and the bus bars 103, for example, the upper horizontal bus bars 103 a, the lower horizontal bus bars 103 d, the cable connection bus bars 103 c, and the transitional bus bars 103 b, as exemplarily illustrated in FIGS. 1A-1B, FIGS. 2-5, and FIGS. 11A-16D. One or more of the compartments 102 a, 102 c, etc., are configured 2402 for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101 for allowing only front access to the electrical cables 111. A mounting block assembly 104, as exemplarily illustrated in FIG. 20C, is positioned 2403 in one or more of the compartments 102, for example, 102 b, 102 d, etc., for providing front access to one or more of the electrical components 113, 118, 119, 120, etc., mounted in the mounting block assembly 104.

One or more the electrical components 113, 118, 119, 120, etc., and the electrical cables 111 are mounted and electrically connected 2404 in predetermined positions in the compartments 102 and/or the mounting block assembly 104 for allowing front access to the electrical components 113, 118, 119, 120, etc., the electrical cables 111, and the bus bars 103 within the electrical enclosure 101. For example, the circuit breaker 118, as exemplarily illustrated in FIGS. 21A-21B, is electrically connected in the middle compartment 102 b defined in the first section 101 a of the electrical enclosure 101 as exemplarily illustrated in FIG. 1B, FIG. 4A, FIG. 11A, and FIG. 15. The electrical cables 111 are accommodated and electrically connected in the front lower compartment 102 c defined in the first section 101 a of the electrical enclosure 101 as exemplarily illustrated in FIGS. 1A-1B, FIG. 3, FIGS. 4A-4B, FIG. 10, FIGS. 11A-11B, and FIG. 13. In an embodiment, the electrical cables 111 enter into and/or exit out from the electrical enclosure 101 via the upper compartment 102 a as exemplarily illustrated in FIGS. 16A-16D.

The control power transformer 119, as exemplarily illustrated in FIGS. 22A-22C, is electrically connected in the middle compartment 102 b defined in the second section 101 b of the electrical enclosure 101 as exemplarily illustrated in FIG. 2, FIG. 5, FIG. 12, and FIG. 14B. The epoxy encapsulated potential transformer 120, as exemplarily illustrated in FIGS. 23A-23C, is electrically connected in the front lower compartment 102 c defined in the second section 101 b of the electrical enclosure 101 as exemplarily illustrated in FIG. 2, FIG. 3, FIG. 5, FIG. 12, and FIG. 14B. The plenum chamber 105 is rearwardly positioned in the first section 101 a of the electrical enclosure 101 and is in adjacent communication with the exhaust chamber 112 as exemplarily illustrated in FIGS. 1A-1B, FIGS. 3-7, FIGS. 9-10, FIGS. 11A-11B, and FIGS. 12-13. One or more of the electrical components 113, 118, 119, 120, etc., and the electrical cables 111 are in electrical communication with one or more of the bus bars 103 in one or more of the compartments 102. One or more infrared windows 108 and inspection windows 109 are positioned at predetermined locations on the front side 100 a of the front accessible switchgear assembly 100 for front scanning the electrical components 113, 118, 119, 120, etc., and the bus bars 103 in the compartments 102 and for providing a front visual indication of the electrical components 118, 119, 120, etc., and the bus bars 103 respectively for inspection and maintenance as exemplarily illustrated in FIGS. 1A-1B, FIG. 2, FIG. 4B, FIG. 6, FIG. 8, FIG. 16B, and FIG. 16D.

FIG. 25 illustrates a method for constructing a multi-access switchgear assembly 1700. An electrical enclosure 101, for example, with a width of 23.62 inches, a depth of 72 inches, and a height of 96 inches is provided 2501. In an embodiment, the width of the electrical enclosure 101 of the multi-access switchgear assembly 1700 may be reduced. The electrical enclosure 101 comprises multiple compartments 102, for example, upper compartments 102 a, middle compartments 102 b, lower compartments 102 c, a central compartment 102 d, rear compartments 102 e, etc., defined in sections, for example, a first section 101 a and a second section 101 b, as exemplarily illustrated in FIGS. 1A-1B, FIGS. 2-16D, and FIGS. 17-19B. The compartments 102 are configured to interchangeably accommodate one or more electrical components, for example, the control equipment, the circuit breaker 118, the control power transformer 119, the epoxy encapsulated potential transformer 120, the electrical cables 111, etc., and the bus bars 103, for example, the upper horizontal bus bars 103 a, the lower horizontal bus bars 103 d, the cable connection bus bars 103 c, and the transitional bus bars 103 b, as exemplarily illustrated in FIG. 17, FIG. 18A, and FIG. 19A. One or more of the compartments, for example, 102 a, 102 c, 102 e, etc., are configured 2502 for enabling the electrical cables 111 to enter into and/or exit out from the electrical enclosure 101 for allowing front access and/or rear access to the electrical cables 111 as exemplarily illustrated in FIG. 17, FIG. 18A, and FIG. 19A. A mounting block assembly 104, as exemplarily illustrated in FIG. 20C, is positioned 2503 in one or more of the compartments 102, for example, 102 b, 102 c, etc., for mounting one or more of the electrical components 113, 118, 119, 120, etc., and for providing front access to the electrical components 113, 118, 119, 120, etc., mounted in the mounting block assembly 104 for inspection and maintenance.

One or more the electrical components 113, 118, 119, 120, etc., and the electrical cables 111 are mounted and electrically connected 2504 in predetermined positions in the compartments 102 and/or the mounting block assembly 104 for allowing front access and/or rear access to the electrical components 113, 118, 119, 120, etc., the electrical cables 111, and the bus bars 103 within the electrical enclosure 101. One or more of the electrical components 113, 118, 119, 120, etc., and the electrical cables 111 are in electrical communication with one or more of the bus bars 103 in one or more of the compartments 102. In an example, the circuit breaker 118, as exemplarily illustrated in FIGS. 21A-21B, is electrically connected in the middle compartment 102 b defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 17 and FIG. 19A. The current transformers 113, as exemplarily illustrated in FIG. 20C, having one of multiple current ratios, are mounted on an input and an output of the circuit breaker 118 via the mounting block assembly 104 as exemplarily illustrated in FIG. 17.

The electrical cables 111 are accommodated and electrically connected in the rear lower compartment 102 e defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 17 and FIGS. 18A-18B. In an embodiment, the electrical cables 111 are accommodated and electrically connected in the front lower compartment 102 c and the rear lower compartment 102 e defined in the electrical enclosure 101, as exemplarily illustrated in 19A-19B. In another embodiment, the electrical cables 111 enter into and/or exit out from the electrical enclosure 101 via the upper compartment 102 a as exemplarily illustrated in FIGS. 16A-16D. The compartments, for example, 102 a, 102 c, 102 e, etc., of the multi-access switchgear assembly 1700 therefore provide front access and/or rear access to the electrical cables 111.

The control power transformer 119, as exemplarily illustrated in FIGS. 22A-22C, having one of multiple power ratings, is electrically connected in the middle compartment 102 b defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 18A. The epoxy encapsulated potential transformer 120, as exemplarily illustrated in FIGS. 23A-23C, having one of multiple voltage levels, is electrically connected, for example, in the front lower compartment 102 c defined in the electrical enclosure 101 as exemplarily illustrated in FIG. 17 and FIG. 18A. The plenum chamber 105 is rearwardly positioned in the electrical enclosure 101 and is in adjacent communication with the exhaust chamber 112 as disclosed in the detailed description of FIG. 17 and as exemplarily illustrated in FIGS. 17-19B. In an embodiment, flaps 106 a, 106 b, and 106 c are positioned between one or more of the compartments 102 and the plenum chamber 105 for isolating one or more of the compartments 102 from the plenum chamber 105 and for preventing gases and external particulate matter from entering the compartments 102 via the plenum chamber 105.

One or more of the electrical components 113, 118, 119, 120, etc., and the electrical cables 111 are in electrical communication with one or more of the bus bars 103 in one or more of the compartments 102. One or more infrared windows 108 and inspection windows 109 are positioned at predetermined locations on the front side 1700 a and/or the rear side 1700 b of the multi-access switchgear assembly 1700 for front scanning and/or rear scanning the electrical components 113, 118, 119, 120, etc., the electrical cables 111, and the bus bars 103 in the compartments 102 and for providing a front visual indication and/or a rear visual indication of the electrical components 118, 119, 120, etc., the electrical cables 111, and the bus bars 103 respectively for inspection and maintenance as exemplarily illustrated in FIG. 17, FIG. 18A, and FIG. 19A. In an embodiment, insulating barriers are provided between high voltage primary connections and the electrical enclosure 101 of the multi-access switchgear assembly 1700 for preventing exposure of active electrical components 119, 120, etc., within the electrical enclosure 101.

The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein can be adapted to flexible configurations to form a family of small footprint switchgear assemblies 100 and 1700 at medium voltage. The flexible configurations provide a smaller footprint for the switchgear assemblies 100 and 1700 that require arc resistance with front access and/or rear access. The front accessible switchgear assembly 100 disclosed herein has full front accessibility making the front accessible switchgear assembly 100 convenient for applications such as data centers, facilities, industrial applications with limited space for medium voltage electrical equipment. The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein are configured, for example, for a voltage rating of 15 kV, 95 kV basic impulse level (BIL), a current rating of 600 A, 1000 A, and 1200 A, a short circuit and short time rating of 31.5 kiloampere (kA), and an arc rating of 25 kA. A control power transformer 119 having up to 15 kVA power is available with the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein.

The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 successfully completed BIL tests at 95 kV, short circuit tests at 31.5 kA, and temperature tests at 1200 A. In addition, all required arc tests were completed at 28 kA at 15.6 kV successfully. The circuit breaker 118 disclosed herein is a magnetically actuated, vacuum circuit breaker that conforms to ANSI/IEEE standards. The mounting block assembly 104 design, epoxy coated bus bars 103, etc., make the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 ultra compact and arc resistant.

Although the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein refer to medium voltage switchgear assemblies, the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein may be extended to a higher voltage switchgear assembly and a lower voltage switchgear assembly with appropriate modifications. The front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein are adapted for 15 kV class equipment, 95 kV lightning impulse voltage, and 1200 A rating and can be extended to higher ratings and used for a low voltage switchgear rated 600V and below. In the front accessible switchgear assembly 100 and the multi-access switchgear assembly 1700 disclosed herein, low voltage 600V current transformers 113 can be used for medium voltage applications at 15000V. This results in substantial savings in cost and space requirements.

The foregoing examples have been provided merely for the purpose of explanation and are in no way to be construed as limiting of the present invention disclosed herein. While the invention has been described with reference to various embodiments, it is understood that the words, which have been used herein, are words of description and illustration, rather than words of limitation. Further, although the invention has been described herein with reference to particular means, materials and embodiments, the invention is not intended to be limited to the particulars disclosed herein; rather, the invention extends to all functionally equivalent structures, methods and uses, such as are within the scope of the appended claims. Those skilled in the art, having the benefit of the teachings of this specification, may affect numerous modifications thereto and changes may be made without departing from the scope and spirit of the invention in its aspects. 

1. A multi-access switchgear assembly, comprising: a plurality of compartments defined within an electrical enclosure, wherein said compartments are configured to interchangeably accommodate one or more electrical components, electrical cables, and bus bars; one or more of said compartments configured for enabling said electrical cables to enter into and/or exit out from said electrical enclosure for allowing front access and/or rear access to said electrical cables; a mounting block assembly positioned in one or more of said compartments for mounting one or more of said electrical components and for providing front access to said mounted one or more electrical components for inspection and maintenance; and said one or more electrical components and said electrical cables electrically connected in predetermined positions in said compartments for allowing said front access and/or rear access to said one or more electrical components, said electrical cables, and said bus bars within said electrical enclosure, wherein one or more of said one or more electrical components and said electrical cables are in electrical communication with one or more of said bus bars in one or more of said compartments.
 2. The multi-access switchgear assembly of claim 1, wherein said mounting block assembly comprises: a plurality of mounting legs extending frontwardly from a base mounting block for mounting said one or more of said electrical components and for allowing said front access to said mounted one or more electrical components; and a mounting block cover removably attached to said base mounting block for enclosing said mounted one or more electrical components on said mounting legs, wherein said mounting block cover is removable for providing said front access to said mounted one or more electrical components for said inspection and said maintenance.
 3. The multi-access switchgear assembly of claim 1, wherein said mounting block assembly is configured to reduce temperature rise in said compartments.
 4. The multi-access switchgear assembly of claim 1, further comprising one or more infrared windows positioned at predetermined locations on one or more of a front side and a rear side of said multi-access switchgear assembly for front scanning and/or rear scanning of said one or more electrical components, said electrical cables, and said bus bars in said compartments for said inspection and said maintenance.
 5. The multi-access switchgear assembly of claim 1, further comprising one or more inspection windows positioned at predetermined locations on one or more of a front side and a rear side of said multi-access switchgear assembly for providing a front visual indication and/or a rear visual indication of said one or more electrical components, said electrical cables, and said bus bars in said compartments for said inspection and said maintenance.
 6. The multi-access switchgear assembly of claim 1, further comprising a plenum chamber rearwardly positioned in said electrical enclosure, wherein said plenum chamber is in communication with one or more of said compartments and provides an exit path for releasing pressure and gases generated by said one or more electrical components and said electrical cables accommodated in said one or more of said compartments during an event of arcing within said electrical enclosure.
 7. The multi-access switchgear assembly of claim 6, further comprising flaps positioned between said compartments and said plenum chamber for preventing said gases and external particulate matter from entering said compartments via said plenum chamber.
 8. The multi-access switchgear assembly of claim 6, wherein said plenum chamber communicates with one or more of said compartments via an exhaust chamber in adjacent communication with said plenum chamber.
 9. The multi-access switchgear assembly of claim 1, wherein one or more of said compartments is configured as a low voltage compartment for accommodating control equipment, wherein said low voltage compartment is isolated from a plenum chamber rearwardly positioned in said electrical enclosure and other of said compartments.
 10. The multi-access switchgear assembly of claim 1, wherein one of said one or more electrical components is a control power transformer having one of a plurality of power ratings electrically connected in a middle one of said compartments.
 11. The multi-access switchgear assembly of claim 10, further comprising one or more fuse sleeve assemblies operably connected to said control power transformer, wherein said one or more fuse sleeve assemblies allow high voltage primary connections of said control power transformer in said electrical enclosure, wherein said one or more fuse sleeve assemblies operably connected to said control power transformer contact one or more of said bus bars in a rear one of said compartments within said electrical enclosure via said mounting block assembly, wherein said mounting block assembly is configured to accommodate each of said one or more fuse sleeve assemblies and isolate phases of said control power transformer.
 12. The multi-access switchgear assembly of claim 10, wherein said control power transformer comprises low voltage contacts configured to disengage from low voltage connections within said electrical enclosure for preventing an event of arcing.
 13. The multi-access switchgear assembly of claim 1, wherein one of said one or more electrical components is a current transformer having one of a plurality of current ratios mounted in said mounting block assembly in one of said compartments.
 14. The multi-access switchgear assembly of claim 1, wherein one of said one or more electrical components is a circuit breaker electrically connected in a middle one of said compartments.
 15. The multi-access switchgear assembly of claim 14, further comprising a cord electrically connected to said circuit breaker for low voltage connection within said electrical enclosure.
 16. The multi-access switchgear assembly of claim 14, wherein another of said one or more electrical components are current transformers having one of a plurality of current ratios, mounted on an input of said circuit breaker and an output of said circuit breaker via said mounting block assembly.
 17. The multi-access switchgear assembly of claim 1, wherein one of said one or more electrical components is an epoxy encapsulated potential transformer having one of a plurality of voltage levels accommodated and electrically connected in one of a middle one of said compartments and a lower one of said compartments.
 18. The multi-access switchgear assembly of claim 17, further comprising one or more fuse sleeve assemblies operably connected to said epoxy encapsulated potential transformer, wherein said one or more fuse sleeve assemblies allow high voltage primary connections of said epoxy encapsulated potential transformer in said electrical enclosure, wherein said one or more fuse sleeve assemblies operably connected to said epoxy encapsulated potential transformer contact one or more of said bus bars in a rear one of said compartments within said electrical enclosure via said mounting block assembly, wherein said mounting block assembly is configured to accommodate each of said one or more fuse sleeve assemblies and isolate phases of said epoxy encapsulated potential transformer.
 19. The multi-access switchgear assembly of claim 17, wherein said epoxy encapsulated potential transformer comprises low voltage contacts configured to disengage from low voltage connections within said electrical enclosure for preventing an event of arcing.
 20. The multi-access switchgear assembly of claim 1, wherein said electrical cables enter into and/or exit out from said electrical enclosure via one or more of an upper one of said compartments, a front one of lower of said compartments, and a rear one of said lower of said compartments.
 21. The multi-access switchgear assembly of claim 1, wherein said bus bars are electrically connected in a rear one of said compartments within said electrical enclosure.
 22. The multi-access switchgear assembly of claim 1 being a metal clad switchgear assembly, wherein adjacent sections defined in said electrical enclosure of said metal clad switchgear assembly are separated by vertical metal barriers for compartmentalizing active electrical components in said electrical enclosure.
 23. The multi-access switchgear assembly of claim 1, wherein said bus bars comprise horizontal bus bars electrically connected in a rear one of said compartments within said electrical enclosure, wherein one or more of said horizontal bus bars allow connection to adjacent sections defined in said electrical enclosure, connection between said one or more electrical components in said adjacent sections defined in said electrical enclosure, connection between said electrical cables in adjacent said compartments in said electrical enclosure and in said adjacent sections defined in said electrical enclosure, and connection to one or more other switchgear assemblies.
 24. The multi-access switchgear assembly of claim 1, further comprising surge arresters positioned in a rear one of said compartments for protecting said electrical components, said bus bars, inspection windows, infrared windows, said electrical cables, said mounting block assembly, and said compartments defined within said electrical enclosure in an event of a lightning surge, wherein said surge arresters are electrically connected to one or more of said bus bars in said electrical enclosure via high voltage electrical cables.
 25. A multi-access switchgear assembly, comprising: a plurality of compartments defined within an electrical enclosure, wherein said compartments are configured to interchangeably accommodate a circuit breaker, current transformers having one or more of a plurality of current ratios, a control power transformer having one of a plurality of power ratings, an epoxy encapsulated potential transformer having one of a plurality of voltage levels, electrical cables, and bus bars; one or more of an upper one of said compartments, a front one of lower of said compartments, and a rear one of said lower of said compartments configured for enabling said electrical cables to enter into and/or exit out from said electrical enclosure for allowing front access and/or rear access to said electrical cables; one or more of said bus bars in electrical communication with one or more of said electrical cables, said circuit breaker, said control power transformer, and said epoxy encapsulated potential transformer in one or more of said compartments; a low voltage compartment configured in one of an upper one of said compartments, a middle one of said compartments, and a lower one of said compartments, wherein said low voltage compartment is isolated from other said compartments; a mounting block assembly positioned in one or more of said compartments for mounting each of said current transformers, said circuit breaker, said control power transformer, and said epoxy encapsulated potential transformer, wherein said mounting block assembly provides front access to said mounted current transformers, said circuit breaker, said control power transformer, and said epoxy encapsulated potential transformer for inspection and maintenance; said circuit breaker mounted in a middle one of said compartments in one of at least two sections of said electrical enclosure and electrically connected within said mounting block assembly, wherein said circuit breaker contacts one or more of said bus bars via said mounting block assembly; said current transformers mounted in said mounting block assembly and adapted for saving space in said electrical enclosure; said control power transformer mounted and electrically connected in a middle one of said compartments in another one of said at least two sections of said electrical enclosure; and said epoxy encapsulated potential transformer mounted and electrically connected in one of a lower one of said compartments and a middle one of said compartments in another one of said at least two sections of said electrical enclosure; whereby said epoxy encapsulated potential transformer, said electrical cables, and one of said circuit breaker and said control power transformer are positioned in a single one of said at least two sections of said multi-access switchgear assembly.
 26. The multi-access switchgear assembly of claim 25, further comprising a plenum chamber rearwardly positioned in said electrical enclosure and in adjacent communication with an exhaust chamber for providing an exit path for releasing pressure and gases generated by said circuit breaker, said current transformers, said control power transformer, said epoxy encapsulated potential transformer, and said electrical cables accommodated in said compartments during an event of arcing within said electrical enclosure.
 27. The multi-access switchgear assembly of claim 25, further comprising one or more fuse sleeve assemblies operably connected to each of said control power transformer and said epoxy encapsulated potential transformer for allowing high voltage primary connections in said electrical enclosure, wherein said one or more fuse sleeve assemblies provide insulating barriers between said high voltage primary connections and said electrical enclosure.
 28. The multi-access switchgear assembly of claim 25, wherein said control power transformer and said epoxy encapsulated potential transformer are electrically connected in one or more of said compartments via said mounting block assembly.
 29. The multi-access switchgear assembly of claim 25 configured to line up with a switchgear having a current rating of about 2000 amperes, thereby enabling usage of said circuit breaker having a current rating of about 1200 amperes and 2000 amperes.
 30. A method for constructing a multi-access switchgear assembly, comprising: providing an electrical enclosure comprising a plurality of compartments, wherein said compartments are configured to interchangeably accommodate one or more electrical components, electrical cables, and bus bars; configuring one or more of said compartments for enabling said electrical cables to enter into and/or exit out from said electrical enclosure for allowing front access and/or rear access to said electrical cables; positioning a mounting block assembly in one or more of said compartments for mounting one or more of said electrical components and for providing front access to said mounted one or more electrical components for inspection and maintenance; and mounting and electrically connecting said one or more electrical components and said electrical cables in predetermined positions in said compartments and said mounting block assembly for allowing said front access and/or rear access to said one or more electrical components, said electrical cables, and said bus bars within said electrical enclosure, wherein one or more of said one or more electrical components and said electrical cables are in electrical communication with one or more of said bus bars in one or more of said compartments.
 31. The method of claim 30, further comprising rearwardly positioning a plenum chamber in said electrical enclosure, wherein said plenum chamber is in communication with one or more of said compartments and in adjacent communication with an exhaust chamber for providing an exit path for releasing pressure and gases generated by said one or more electrical components and said electrical cables accommodated in said one or more of said compartments during an event of arcing within said electrical enclosure.
 32. The method of claim 31, further comprising isolating one or more of said compartments and said plenum chamber by one or more flaps positioned between said one or more compartments and said plenum chamber for preventing said gases and external particulate matter from entering said one or more compartments via said plenum chamber.
 33. The method of claim 30, further comprising providing insulating barriers between high voltage primary connections and said electrical enclosure of said multi-access switchgear assembly for preventing exposure of active electrical components within said electrical enclosure. 